Crispr/cas-related methods and compositions for treating sickle cell disease

ABSTRACT

CRISPR/CAS-related compositions and methods for treatment of Sickle Cell Disease (SCD) are disclosed.

REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. application Ser. No. 15/129,367, filed Sep. 26, 2016, which is a national phase of International Application No. PCT/US2015/022856, filed Mar. 26, 2015, which claims the benefit of U.S. Provisional Application No. 61/970,588, filed Mar. 26, 2014, and U.S. Provisional Application No. 62/084,487, filed Nov. 25, 2014, the contents of each of which are hereby incorporated by reference in their entirety.

FIELD OF THE INVENTION

The invention relates to CRISPR/CAS-related methods and components for editing of a target nucleic acid sequence, or modulating expression of a target nucleic acid sequence, and applications thereof in connection with Sickle Cell Disease (SCD).

SEQUENCE LISTING

This application contains a Sequence Listing, which was submitted in ASCII format via EFS-Web, and is hereby incorporated by reference in its entirety. The ASCII copy, created on Jan. 19, 2022, is named SequenceListing.txt and is 3,905 KB in size.

BACKGROUND

Sickle Cell Disease (SCD), also known as Sickle Cell Anemia (SCA), is a common inherited hematologic disease. It affects 80,000-90,000 people in the United States. It is common in people of African descent and in Hispanic-Americans with the prevalence of SCD being 1 in 500 and 1 in 1,000, respectively.

SCD is caused by a mutation in the beta-globin (HBB) gene. HBB is located on chromosome 11 within the HBB gene cluster, which includes genes encoding the delta globin chain, A gamma chain, G gamma chain. The alpha-globin gene is located on chromosome 16. A point mutation (e.g., GAG→GTG) results in the substitution of valine for glutamic acid at amino acid position 6 in exon 1 of the HBB gene. Beta hemoglobin chains with this mutation are expressed as HbS. The disease is inherited in an autosomal recessive manner, so that only patients with two HbS alleles have SCD. Subjects who have sickle cell trait (are heterozygous for HbS) only display a phenotype if they are severely dehydrated or oxygen deprived.

Normal adult hemoglobin (Hb) is composed of a tetramer made from two alpha-globin chains and two beta-globin chains. In SCD, the valine at position 6 of the beta-chain is hydrophobic and causes a change in conformation of the beta-globin protein when it is not bound to oxygen. HbS is more likely to polymerize and leads to the characteristic sickle shaped red blood cells (RBCs) found in SCD.

Sickle shape RBCs cause multiple manifestations of disease, which include, e.g., anemia, sickle cell crises, vaso-occlusive crises, aplastic crises and acute chest syndrome. The disease has varous manifestations, e.g., vaso-occlusive crisis, splenic sequestration crisis and anemia. Subjects may also suffer from acute chest crisis and infarcts of extremities, end organs and central nervous system. Treatment includes, e.g., hydration, transfusion and analgesics. Treatment of SCD also includes, e.g., the use of hydroxyurea, supplementation with folic acid, and penicillin prophylaxis during childhood. Bone marrow transplants have been demonstrated to cure SCD.

Thus, there remains a need for additional methods and compositions that can be used to treat SCD.

SUMMARY OF THE INVENTION

Methods and compositions discussed herein, provide for the treatment and prevention of Sickle Cell Disease (SCD), also known as Sickle Cell Anemia (SCA). SCD is an inherited hematologic disease.

In healthy individuals, two beta-globin molecules pair with two alpha-globin molecules to form normal hemoglobin (Hb). In SCD, mutations in the beta-globin (HBB) gene, e.g., a point mutation (GAG→GTG) that results in the substitution of valine for glutamic acid at amino acid position 6 of the beta-globin molecule, cause production of sickle hemoglobin (HbS). HbS is more likely to polymerize and leads to the characteristic sickle shaped red blood cells (RBCs). Sickle shaped RBCs give rise to multiple manifestations of disease, such as, anemia, sickle cell crises, vaso-occlusive crises, aplastic crises and acute chest syndrome. Alpha-globin can also pair with fetal hemoglobin (HbF), which significantly moderates the severe anemia and other symptoms of SCD. However, the expression of HbF is negatively regulated by the BCL11A gene product.

Methods and compositions disclosed herein provide a number of approaches for treating SCD. As is discussed in more detail below, methods described herein provide for treating SCD by correcting a target position in the HBB gene to provide corrected, or functional, e.g., wild type, beta-globin. Methods and compositions discussed herein can be used to treat or prevent SCD by altering the BCL11A gene (also known as B-cell CLL/lymphoma 11A, BCL11A-L, BCL11A-S, BCL11A-XL, CTIP1, HBFQTL5 and ZNF). BCL11A encodes a zinc-finger protein that is involved in the regulation of globin gene expression. By altering the BCL11A gene (e.g., one or both alleles of the BCL11A gene), the levels of gamma globin can be increased. Gamma globin can replace beta globin in the hemoglobin complex and effectively carry oxygen to tissues, thereby ameliorating SCD disease phenotypes.

In one aspect, methods and compositions discussed herein, provide for the correction of the underlying genetic cause of SCD, e.g., the correction of a mutation at a target position in the HBB gene, e.g., correction of a mutation at amino acid position 6, e.g., an E6V substitution in the HBB gene.

Mutations in the HBB gene (also known as beta-globin and CD113t-C) have been shown to cause SCD. Mutations leading to SCD can be described based on their target positions in the HBB gene. In an embodiment, the target position is E6, e.g., E6V, in the HBB gene.

“SCD target point position”, as used herein, refers to a target position in the HBB gene, typically a single nucleotide, which, if mutated, can result in a protein having a mutant amino acid and give rise to SCD. In an embodiment, the SCD target position is the target position at which a change can give rise to an E6 mutant protein, e.g., a protein having an E6V substitution.

While much of the disclosure herein is presented in the context of the mutation in the HBB gene that gives rise to an E6 mutant protein (e.g., E6V mutant protein), the methods and compositions herein are broadly applicable to any mutation, e.g., a point mutation or a deletion, in the HBB gene that gives rise to SCD.

While not wishing to be bound by theory, it is believed that, in an embodiment, a mutation at an SCD target point position in the HBB gene is corrected, e.g., by homology directed repair (HDR), as described herein.

In one aspect, methods and compositions discussed herein may be used to alter the BCL11A gene to treat or prevent SCD, by targeting the BCL11A gene, e.g., coding or non-coding regions of the BCL11A gene. Altering the BCL11A gene herein refers to reducing or eliminating (1) BCL11A gene expression, (2) BCL11A protein function, or (3) the level of BCL11A protein.

In an embodiment, the coding region (e.g., an early coding region) of the BCL11A gene is targeted for alteration. In an embodiment, a non-coding sequence (e.g., an enhancer region, a promoter region, an intron, 5′UTR, 3′UTR, or polyadenylation signal) is targeted for alteration.

In an embodiment, the method provides an alteration that comprises disrupting the BCL11A gene by the insertion or deletion of one or more nucleotides mediated by Cas9 (e.g., enzymatically active Cas9 (eaCas9), e.g., Cas9 nuclease or Cas9 nickase) as described below. This type of alteration is also referred to as “knocking out” the BCL11A gene.

In another embodiment, the method provides an alteration that does not comprise nucleotide insertion or deletion in the BCL11A gene and is mediated by enzymatically inactive Cas9 (eiCas9) or an eiCas9-fusion protein, as described below. This type of alteration is also referred to as “knocking down” the BCL11A gene.

In an embodiment, the methods and compositions discussed herein may be used to alter the BCL11A gene to treat or prevent SCD by knocking out one or both alleles of the BCL11A gene. In an embodiment, the coding region (e.g., an early coding region) of the BCL11A gene, is targeted to alter the gene. In an embodiment, a non-coding region of the BCL11A gene (e.g., an enhancer region, a promoter region, an intron, 5′ UTR, 3′UTR, polyadenylation signal) is targeted to alter the gene. In an embodiment, an enhancer (e.g., a tissue-specific enhancer, e.g., a myeloid enhancer, e.g., an erythroid enhancer) is targeted to alter the gene. BCL11A erythroid enhancer comprises an approximate 12.4 kb fragment of BCL11A intron2, located between approximate+52.0 to +64.4 kilobases (kb) from the Transcription Start Site (TSS+52 kb to TSS+64.4 kb, see FIG. 10 ). It's also referred to herein as chromosome 2 location 60,716,189-60,728,612 (according to UCSC Genome Browser hg 19 human genome assembly). Three deoxyribonuclese I hypersensitive sites (DHSs), TSS+62 kb, TSS+58 kb and TSS+55 kb are located in this region. Deoxyribonuclease I sensitivity is a marker for gene regulatory elements. While not wishing to be bound by theory, it's believed that deleting the ehancer region (e.g., TSS+52 kb to TSS+64.4 kb) may reduce or eliminate BCL11A expression in erythroid precursors which leads to gamma globin derepression while sparing BCL11A expression in nonerythoroid lineages. In an embodiment, the method provides an alteration that comprises a deletion of the enhancer region (e.g., a tissue-specific enhancer, e.g., a myleloid enhancer, e.g., an erythroid enhancer) or a protion of the region resulting in disruption of one or more DNase 1-hypersensitivie sites (DHS). In an embodiment, the method provides an alteration that comprises an insertion or deletion of one or more nucleotides. As described herein, in an embodiment, a targeted knockout approach is mediated by non-homologous end joining (NHEJ) using a CRISPR/Cas system comprising an enzymatically active Cas9 (eaCas9). In an embodiment, a targeted knockout approach alters the BCL11A gene. In an embodiment, a targeted knockout approach reduces or eliminates expression of functional BCL11A gene product. In an embodiment, targeting affects one or both alleles of the BCL11A gene. In an embodiment, an enhancer disruption approach reduces or eliminates expression of functional BCL11A gene product in the erythroid lineage.

“SCD target knockout position”, as used herein, refers to a position in the BCL11A gene, which if altered, e.g., disrupted by insertion or deletion of one or more nucleotides, e.g., by NHEJ-mediated alteration, results in reduction or elimination of expression of functional BCL11A gene product. In an embodiment, the position is in the BCL11A coding region, e.g., an early coding region. In an embodiment, the position is in the BCL11A non-coding region, e.g., an enhancer region.

In an embodiment, methods and compositions discussed herein, provide for altering (e.g., knocking out) the BCL11A gene. In an embodiment, knocking out the BCL11A gene herein refers to (1) insertion or deletion (e.g., NHEJ-mediated insertion or deletion) of one or more nucleotides in close proximity to or within the early coding region of the BCL11A gene, or (2) deletion (e.g., NHEJ-mediated deletion) of a genomic sequence including the erythroid enhancer of the BCL11A gene,

In an embodiment, the SCD target knockout position is altered by genome editing using the CRISPR/Cas9 system. The SCD target knockout position may be targeted by cleaving with either a single nuclease or dual nickases, e.g., to induce insertion or deletion (e.g., NHEJ-mediated insertion or deletion) of one or more nucleotides in close proximity to or within the early coding region of the SCD target knockout position or to delete (e.g., mediated by NHEJ) a genomic sequence including the erythroid enhancer of the BCL11A gene.

In an embodiment, the methods and compositions described herein introduce one or more breaks in close proximity to or within the early coding region in at least one allele of the BCL11A gene. In an embodiment, a single strand break is introduced in close proximity to or within the early coding region in at least one allele of the BCL11A gene. In an embodiment, the single strand break will be accompanied by an additional single strand break, positioned by a second gRNA molecule.

In an embodiment, a double strand break is introduced in close proximity to or within the early coding region in at least one allele of the BCL11A gene. In an embodiment, a double strand break will be accompanied by an additional single strand break positioned by a second gRNA molecule. In an embodiment, a double strand break will be accompanied by two additional single strand breaks positioned by a second gRNA molecule and a third gRNA molecule.

In an embodiment, a pair of single strand breaks is introduced in close proximity to or within the early coding region in at least one allele of the BCL11A gene. In an embodiment, the pair of single strand breaks will be accompanied by an additional double strand break, positioned by a third gRNA molecule. In an embodiment, the pair of single strand breaks will be accompanied by an additional pair of single strand breaks positioned by a third gRNA molecule and a fourth gRNA molecule.

In an embodiment, two double strand breaks are introduced to flank the erythroid enhancer at the in the BCL11A gene (one 5′ and the other one 3′ to the erythroid enhancer) to remove (e.g., delete) the genomic sequence including the erythroid enhancer. It is contemplated herein that in an embodiment the deletion of the genomic sequence including the erythroid enhancer is mediated by NHEJ. In an embodiment, the breaks (i.e., the two double strand breaks) are positioned to avoid unwanted deletion of certain elements, such as endogenous splice sites. The breaks, i.e., two double strand breaks, can be positioned upstream and downstream of the erythroid enhancer, as discussed herein.

In an embodiment, two sets of breaks (e.g., one double strand break and a pair of single strand breaks) are introduced to flank the erythroid enhancer in the BCL11A gene (one set 5′ and the other set 3′ to the erythroid enhancer) to remove (e.g., delete) the genomic sequence including the erythroid enhancer. It is contemplated herein that in an embodiment the deletion of the genomic sequence including the erythroid enhancer is mediated by NHEJ. In an embodiment, the breaks (i.e., the double strand break and the pair of single strand breaks) are positioned to avoid unwanted deletion of certain chromosome elements, such as endogenous splice sites. The breaks, e.g., the double strand break and the pair of single strand breaks, can be positioned upstream and downstream of the erythroid enhancer, as discussed herein.

In an embodiment, two sets of breaks (e.g., two pairs of single strand breaks) are introduced to flank the erythroid enhancer at the SCD target position in the BCL11A gene (one set 5′ and the other set 3′ to the erythroid enhancer) to remove (e.g., delete) the genomic sequence including the erythroid enhancer. It is contemplated herein that in an embodiment the deletion of the genomic sequence including the erythroid enhancer is mediated by NHEJ. In an embodiment, the breaks (i.e., the two pairs of single strand breaks) are positioned to avoid unwanted deletion of certain chromosome elements, such as endogenous splice sites. The breaks, e.g., the two pairs of single strand breaks, can be positioned upstream and downstream of the erythroid enhancer, as discussed herein.

In an embodiment, the methods and compositions discussed herein may be used to alter the BCL11A gene to treat or prevent SCD by knocking down one or both alleles of the BCL11A gene. In one embodiment, the coding region of the BCL11A gene, is targeted to alter the gene. In another embodiment, a non-coding region (e.g., an enhancer region, a promoter region, an intron, 5′ UTR, 3′UTR, polyadenylation signal) of the BCL11A gene is targeted to alter the gene. In an embodiment, the promoter region of the BCL11A gene is targeted to knock down the expression of the BCL11A gene. A targeted knockdown approach alters, e.g., reduces or eliminates the expression of the BCL11A gene. As described herein, in an embodiment, a targeted knockdown is mediated by targeting an enzymatically inactive Cas9 (eiCas9) or an eiCas9 fused to a transcription repressor domain or chromatin modifying protein to alter transcription, e.g., to block, reduce, or decrease transcription, of the BCL11A gene.

“SCD target knockdown position”, as used herein, refers to a position, e.g., in the BCL11A gene, which if targeted by an eiCas9 or an eiCas9 fusion described herein, results in reduction or elimination of expression of functional BCL11A gene product. In an embodiment, transcription is reduced or eliminated. In an embodiment, the position is in the BCL11A promoter sequence. In an embodiment, a position in the promoter sequence of the BCL11A gene is targeted by an enzymatically inactive Cas9 (eiCas9) or an eiCas9-fusion protein, as described herein.

In an embodiment, one or more gRNA molecule comprising a targeting domain configured to target an enzymatically inactive Cas9 (eiCas9) or an eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain), sufficiently close to a SCD target knockdown position to reduce, decrease or repress expression of the BCL11A gene.

“SCD target position”, as used herein, refers to any of an SCD target point position, SCD target knockout position, or SCD target knockdown position, as described herein.

In one aspect, disclosed herein is a gRNA molecule, e.g., an isolated or non-naturally occurring gRNA molecule, comprising a targeting domain which is complementary with a target domain from the HBB gene or BCL11A gene.

When two or more gRNAs are used to position two or more cleavage events, e.g., double strand or single strand breaks, in a target nucleic acid, it is contemplated that the two or more cleavage events may be made by the same or different Cas9 proteins. For example, when two gRNAs are used to position two double strand breaks, a single Cas9 nuclease may be used to create both double strand breaks. When two or more gRNAs are used to position two or more single stranded breaks (single strand breaks), a single Cas9 nickase may be used to create the two or more single strand breaks. When two or more gRNAs are used to position at least one double strand break and at least one single strand break, two Cas9 proteins may be used, e.g., one Cas9 nuclease and one Cas9 nickase. It is contemplated that when two or more Cas9 proteins are used that the two or more Cas9 proteins may be delivered sequentially to control specificity of a double strand versus a single strand break at the desired position in the target nucleic acid.

In an embodiment, the targeting domain of the first gRNA molecule and the targeting domain of the second gRNA molecule hybridize to the target domain through complementary base pairing to opposite strands of the target nucleic acid molecule. In an embodiment, the gRNA molecule and the second gRNA molecule are configured such that the PAMs are oriented outward.

In an embodiment, the targeting domain of a gRNA molecule is configured to avoid unwanted target chromosome elements, such as repeat elements, e.g., an Alu repeat, or the endogenous splice sites, in the target domain. The gRNA molecule may be a first, second, third and/or fourth gRNA molecule.

In an embodiment, the targeting domain of a gRNA molecule is configured to position a cleavage event sufficiently far from a preselected nucleotide, e.g., the nucleotide of a coding region, such that the nucleotide is not altered. In an embodiment, the targeting domain of a gRNA molecule is configured to position an intronic cleavage event sufficiently far from an intron/exon border, or naturally occurring splice signal, to avoid alteration of the exonic sequence or unwanted splicing events. The gRNA molecule may be a first, second, third and/or fourth gRNA molecule, as described herein.

In an embodiment, a point mutation in the HBB gene, e.g., at E6, e.g., E6V, is targeted, e.g., for correction. In an embodiment, the targeting domain of a gRNA molecule comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 1A-1D. In an embodiment, the targeting domain is selected from those in Tables 1A-1D. For example, in an embodiment, the targeting domain is:

(SEQ ID NO: 387) AAGGUGAACGUGGAUGAAGU; (SEQ ID NO: 388) GUAACGGCAGACUUCUCCUC; (SEQ ID NO: 389) GUGAACGUGGAUGAAGU; or (SEQ ID NO: 390) ACGGCAGACUUCUCCUC.

In an embodiment, when the SCD target point position is E6, e.g., E6V, and two gRNAs are used to position two breaks, e.g., two single stranded breaks, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Tables 1A-1D.

In an embodiment, a point mutation in the HBB gene, e.g., at E6, e.g., E6V, is targeted, e.g., for correction. In an embodiment, the targeting domain of a gRNA molecule comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 13A-13D. In an embodiment, the targeting domain is selected from those in Tables 13A-13D. For example, in an embodiment, the targeting domain is:

(SEQ ID NO: 6803) GGUGCACCUGACUCCUG; or (SEQ ID NO: 6804) GUAACGGCAGACUUCUCCAC.

In an embodiment, when the SCD target point position is E6, e.g., E6V, and two gRNAs are used to position two breaks, e.g., two single stranded breaks, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Tables 13A-13D.

In an embodiment, a point mutation in the HBB gene, e.g., at E6, e.g., E6V, is targeted, e.g., for correction. In an embodiment, the targeting domain of a gRNA molecule comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 14A-14C. In an embodiment, the targeting domain is selected from those in Tables 14A-14C.

In an embodiment, when the SCD target point position is E6, e.g., E6V, and two gRNAs are used to position two breaks, e.g., two single stranded breaks, in the target nucleic acid sequence, each guide RNA is selected from one of Tables 14A-14C.

In an embodiment, a point mutation in the HBB gene, e.g., at E6, e.g., E6V, is targeted, e.g., for correction. In an embodiment, the targeting domain of a gRNA molecule comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 24A-24D. In an embodiment, the targeting domain is selected from those in Tables 24A-24D.

In an embodiment, when the SCD target point position is E6, e.g., E6V, and two gRNAs are used to position two breaks, e.g., two single stranded breaks, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Tables 24A-24D.

In an embodiment, a point mutation in the HBB gene, e.g., at E6, e.g., E6V, is targeted, e.g., for correction. In an embodiment, the targeting domain of a gRNA molecule comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 25A-25B. In an embodiment, the targeting domain is selected from those in Tables 25A-25B.

In an embodiment, when the SCD target point position is E6, e.g., E6V, and two gRNAs are used to position two breaks, e.g., two single stranded breaks, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Tables 25A-25B.

In an embodiment, a point mutation in the HBB gene, e.g., at E6, e.g., E6V, is targeted, e.g., for correction. In an embodiment, the targeting domain of a gRNA molecule comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from Table 26. In an embodiment, the targeting domain is selected from those in Table 26.

In an embodiment, when the SCD target point position is E6, e.g., E6V, and two gRNAs are used to position two breaks, e.g., two single stranded breaks, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from Table 26. In another embodiment, a position in the coding region, e.g., the early coding region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 2A-2F. In an embodiment, the targeting domain is selected from those in Tables 2A-2F. In another embodiment, the targeting domain is:

(SEQ ID NO: 486) UGGCAUCCAGGUCACGCCAG; (SEQ ID NO: 487) GAUGCUUUUUUCAUCUCGAU; (SEQ ID NO: 488) GCAUCCAAUCCCGUGGAGGU; (SEQ ID NO: 489) UUUUCAUCUCGAUUGGUGAA; (SEQ ID NO: 490) CCAGAUGAACUUCCCAUUGG; (SEQ ID NO: 491) AGGAGGUCAUGAUCCCCUUC; (SEQ ID NO: 492) CAUCCAGGUCACGCCAG; (SEQ ID NO: 493) GCUUUUUUCAUCUCGAU; (SEQ ID NO: 494) UCCAAUCCCGUGGAGGU; (SEQ ID NO: 495) UCAUCUCGAUUGGUGAA; (SEQ ID NO: 496) GAUGAACUUCCCAUUGG; or (SEQ ID NO: 497) AGGUCAUGAUCCCCUUC.

In an embodiment, when the SCD target knockout position is the BCL11A coding region, e.g., early coding region, and more than one gRNA is used to position breaks, e.g., two single stranded breaks or two double stranded breaks, or a combination of single strand and double strand breaks, e.g., to create one or more indels, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Tables 2A-2F.

In another embodiment, a position in the coding region, e.g., the early coding region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Table 4A-4E. In an embodiment, the targeting domain is selected from those in Table 4A-4E. In another embodiment, the targeting domain is:

(SEQ ID NO: 3073) GAGCUCCAUGUGCAGAACGA; (SEQ ID NO: 3074) GAGCUCCCAACGGGCCG; (SEQ ID NO: 3075) GAGUGCAGAAUAUGCCCCGC; (SEQ ID NO: 3076) GAUAAACAAUCGUCAUCCUC; (SEQ ID NO: 3077) GAUGCCAACCUCCACGGGAU; (SEQ ID NO: 3078) GCAGAAUAUGCCCCGCA; (SEQ ID NO: 3079) GCAUCCAAUCCCGUGGAGGU; (SEQ ID NO: 3080) GCCAACCUCCACGGGAU; (SEQ ID NO: 3081) GCUCCCAACGGGCCGUGGUC; or (SEQ ID NO: 3082) GGAGCUCUAAUCCCCACGCC.

In an embodiment, when the SCD target knockout position is the BCL11A coding region, e.g., early coding region, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create one or more indels, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 4A-4E.

In another embodiment, a position in the coding region, e.g., the early coding region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Table 5A-5E. In an embodiment, the targeting domain is selected from those in Table 5A-5E.

In an embodiment, when the SCD target knockout position is the BCL11A coding region, e.g., early coding region, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create one or more indels, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 5A-5E.

In another embodiment, a position in the coding region, e.g., the early coding region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Table 6A-6B. In an embodiment, the targeting domain is selected from those in Table 6A-6B.

In an embodiment, when the SCD target knockout position is the BCL11A coding region, e.g., early coding region, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create one or more indels, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 6A-6B.

In another embodiment, a position in the coding region, e.g., the early coding region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Table 15A-15D. In an embodiment, the targeting domain is selected from those in Table 15A-15D.

In an embodiment, when the SCD target knockout position is the BCL11A coding region, e.g., early coding region, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create one or more indels, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 15A-15D.

In another embodiment, a position in the coding region, e.g., the early coding region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Table 16A-16E. In an embodiment, the targeting domain is selected from those in Table 16A-16E.

In an embodiment, when the SCD target knockout position is the BCL11A coding region, e.g., early coding region, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create one or more indels, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 16A-16E.

In another embodiment, a position in the coding region, e.g., the early coding region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Table 17A-17B. In an embodiment, the targeting domain is selected from those in Table 17A-17B.

In an embodiment, when the SCD target knockout position is the BCL11A coding region, e.g., early coding region, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create one or more indels, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 17A-17B.

In another embodiment, a position in the non-coding region, e.g., the enhancer region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 7A-7D. In an embodiment, the targeting domain is selected from those in Tables 7A-7D. In another embodiment, the targeting domain is:

(SEQ ID NO: 4835) GAAAAUACUUACUGUACUGC; (SEQ ID NO: 4836) GAAAGCAGUGUAAGGCU; (SEQ ID NO: 4837) GGCUGUUUUGGAAUGUAGAG; or (SEQ ID NO: 4838) GUGCUACUUAUACAAUUCAC.

In an embodiment, when the SCD target knockout position is the non-coding region, e.g., the enhancer region, of the BCL11A gene, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create a deletion, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 7A-7D.

In another embodiment, a position in the non-coding region, e.g., the enhancer region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 8A-8D. In an embodiment, the targeting domain is selected from those in Tables 8A-8D.

In an embodiment, when the SCD target knockout position is the non-coding region, e.g., the enhancer region, of the BCL11A gene, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create a deletion, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 8A-8D.

In another embodiment, a position in the non-coding region, e.g., the enhancer region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from Table 9. In an embodiment, the targeting domain is selected from those in Table 9.

In an embodiment, when the SCD target knockout position is the non-coding region, e.g., the enhancer region, of the BCL11A gene, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create a deletion, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 9.

In another embodiment, a position in the non-coding region, e.g., the enhancer region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 21A-21E. In an embodiment, the targeting domain is selected from those in Tables 21A-21E. In an embodiment, when the SCD target knockout position is the non-coding region, e.g., the enhancer region, of the BCL11A gene, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create a deletion, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 21A-21E.

In another embodiment, a position in the non-coding region, e.g., the enhancer region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 22A-22E. In an embodiment, the targeting domain is selected from those in Tables 22A-22E. In an embodiment, when the SCD target knockout position is the non-coding region, e.g., the enhancer region, of the BCL11A gene, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create a deletion, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 22A-22E.

In another embodiment, a position in the non-coding region, e.g., the enhancer region, of the BCL11A gene is targeted, e.g., for knockout. In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 23A-23C. In an embodiment, the targeting domain is selected from those in Tables 23A-23C.

In an embodiment, when the SCD target knockout position is the non-coding region, e.g., the enhancer region, of the BCL11A gene, and more than one gRNA is used to position breaks, e.g., two single strand breaks or two double strand breaks, or a combination of single strand and double strand breaks, e.g., to create a deletion, in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Table 23A-23C.

In an embodiment, the targeting domain of the gRNA molecule is configured to target an enzymatically inactive Cas9 (eiCas9) or an eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain), sufficiently close to an SCD knockdown target position to reduce, decrease or repress expression of the BCL11A gene. In an embodiment, the targeting domain is configured to target the promoter region of the BCL11A gene to block transcription initiation, binding of one or more transcription enhancers or activators, and/or RNA polymerase. One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

In an embodiment, when the BCL11A promoter region is targeted, e.g., for knockdown, the targeting domain can comprise a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 3A-3C. In an embodiment, the targeting domain is selected from those in Tables 3A-3C.

In an embodiment, when the SCD target knockdown position is the BCL11A promoter region and more than one gRNA is used to position an eiCas9 or an eiCas9-fusion protein (e.g., an eiCas9-transcription repressor domain fusion protein), in the target nucleic acid sequence, the targeting domain of each guide RNA is selected from one of Tables 3A-3C.

In an embodiment, when the BCL11A promoter region is targeted, e.g., for knockdown, the targeting domain can comprise a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 10A-10D. In an embodiment, the targeting domain is selected from those in Tables 10A-10D. In another embodiment, the targeting domain is:

(SEQ ID NO: 4981) GACGACGGCUCGGUUCACAU; (SEQ ID NO: 4982) GACGCCAGACGCGGCCCCCG; (SEQ ID NO: 4983) GCCUUGCUUGCGGCGAGACA; (SEQ ID NO: 4984) GGCUCCGCGGACGCCAGACG; (SEQ ID NO: 4985) GACGGCUCGGUUCACAU; (SEQ ID NO: 4986) GCCGCGUCUGGCGUCCG; or (SEQ ID NO: 4987) GCGGGCGGACGACGGCU.

In an embodiment, when the SCD target knockdown position is the BCL11A promoter region and more than one gRNA is used to position an eiCas9 or an eiCas9-fusion protein (e.g., an eiCas9-transcription repressor domain fusion protein), in the target nucleic acid sequence, each guide RNA is selected from one of Tables 10A-10D.

In an embodiment, when the BCL11A promoter region is targeted, e.g., for knockdown, the targeting domain can comprise a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 11A-11D. In an embodiment, the targeting domain is selected from those in Tables 11A-11D.

In an embodiment, when the SCD target knockdown position is the BCL11A promoter region and more than one gRNA is used to position an eiCas9 or an eiCas9-fusion protein (e.g., an eiCas9-transcription repressor domain fusion protein), in the target nucleic acid sequence, each guide RNA is selected from one of Tables 11A-11D.

In an embodiment, when the BCL11A promoter region is targeted, e.g., for knockdown, the targeting domain can comprise a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from Table 12. In an embodiment, the targeting domain is selected from those in Table 12.

In an embodiment, when the SCD target knockdown position is the BCL11A promoter region and more than one gRNA is used to position an eiCas9 or an eiCas9-fusion protein (e.g., an eiCas9-transcription repressor domain fusion protein), in the target nucleic acid sequence, each guide RNA is selected from Table 12.

In an embodiment, when the BCL11A promoter region is targeted, e.g., for knockdown, the targeting domain can comprise a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 18A-18C. In an embodiment, the targeting domain is selected from those in Tables 18A-18C.

In an embodiment, when the SCD target knockdown position is the BCL11A promoter region and more than one gRNA is used to position an eiCas9 or an eiCas9-fusion protein (e.g., an eiCas9-transcription repressor domain fusion protein), in the target nucleic acid sequence, each guide RNA is selected from one of Tables 18A-18C.

In an embodiment, when the BCL11A promoter region is targeted, e.g., for knockdown, the targeting domain can comprise a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 19A-19E. In an embodiment, the targeting domain is selected from those in Tables 19A-19E.

In an embodiment, when the SCD target knockdown position is the BCL11A promoter region and more than one gRNA is used to position an eiCas9 or an eiCas9-fusion protein (e.g., an eiCas9-transcription repressor domain fusion protein), in the target nucleic acid sequence, each guide RNA is selected from one of Tables 19A-19E.

In an embodiment, when the BCL11A promoter region is targeted, e.g., for knockdown, the targeting domain can comprise a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 20A-20C. In an embodiment, the targeting domain is selected from those in Tables 20A-20C.

In an embodiment, when the SCD target knockdown position is the BCL11A promoter region and more than one gRNA is used to position an eiCas9 or an eiCas9-fusion protein (e.g., an eiCas9-transcription repressor domain fusion protein), in the target nucleic acid sequence, each guide RNA is selected from one of Tables 20A-20C.

In an embodiment, the targeting domain comprises a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence selected from any one of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. In an embodiment, the targeting domain is selected from those in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31.

In an embodiment, the targeting domain which is complementary with the BCL11A gene is 16 nucleotides or more in length. In an embodiment, the targeting domain is 16 nucleotides in length. In an embodiment, the targeting domain is 17 nucleotides in length. In another embodiment, the targeting domain is 18 nucleotides in length. In still another embodiment, the targeting domain is 19 nucleotides in length. In still another embodiment, the targeting domain is 20 nucleotides in length. In still another embodiment, the targeting domain is 21 nucleotides in length. In still another embodiment, the targeting domain is 22 nucleotides in length. In still another embodiment, the targeting domain is 23 nucleotides in length. In still another embodiment, the targeting domain is 24 nucleotides in length. In still another embodiment, the targeting domain is 25 nucleotides in length. In still another embodiment, the targeting domain is 26 nucleotides in length.

In an embodiment, the targeting domain comprises 16 nucleotides.

In an embodiment, the targeting domain comprises 17 nucleotides.

In an embodiment, the targeting domain comprises 18 nucleotides.

In an embodiment, the targeting domain comprises 19 nucleotides.

In an embodiment, the targeting domain comprises 20 nucleotides.

In an embodiment, the targeting domain comprises 21 nucleotides.

In an embodiment, the targeting domain comprises 22 nucleotides.

In an embodiment, the targeting domain comprises 23 nucleotides.

In an embodiment, the targeting domain comprises 24 nucleotides.

In an embodiment, the targeting domain comprises 25 nucleotides.

In an embodiment, the targeting domain comprises 26 nucleotides.

In an embodiment, the gRNA, e.g., a gRNA comprising a targeting domain, which is complementary with the HBB gene or BCL11A gene, is a modular gRNA. In another embodiment, the gRNA is a unimolecular or chimeric gRNA.

HBB gRNA as described herein may comprise from 5′ to 3′: a targeting domain (comprising a “core domain”, and optionally a “secondary domain”); a first complementarity domain; a linking domain; a second complementarity domain; a proximal domain; and a tail domain. In an embodiment, the proximal domain and tail domain are taken together as a single domain.

In an embodiment, a gRNA comprises a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 20 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In another embodiment, a gRNA comprises a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 25 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In another embodiment, a gRNA comprises a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 30 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In another embodiment, a gRNA comprises a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 40 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

A cleavage event, e.g., a double strand or single strand break, is generated by a Cas9 molecule. The Cas9 molecule may be an enzymatically active Cas9 (eaCas9) molecule, e.g., an eaCas9 molecule that forms a double strand break in a target nucleic acid or an eaCas9 molecule forms a single strand break in a target nucleic acid (e.g., a nickase molecule). Alternatively, in an embodiment, the Cas9 molecule may be an enzymatically inactive Cas9 (eiCas9) molecule or a modified eiCas9 molecule, e.g., the eiCas9 molecule is fused to Krüppel-associated box (KRAB) to generate an eiCas9-KRAB fusion protein molecule.

In an embodiment, the eaCas9 molecule catalyzes a double strand break.

In an embodiment, the eaCas9 molecule comprises HNH-like domain cleavage activity but has no, or no significant, N-terminal RuvC-like domain cleavage activity. In this case, the eaCas9 molecule is an HNH-like domain nickase, e.g., the eaCas9 molecule comprises a mutation at D10, e.g., D10A. In another embodiment, the eaCas9 molecule comprises N-terminal RuvC-like domain cleavage activity but has no, or no significant, HNH-like domain cleavage activity. In an embodiment, the eaCas9 molecule is an N-terminal RuvC-like domain nickase, e.g., the eaCas9 molecule comprises a mutation at H840, e.g., H840A. In an embodiment, the eaCas9 molecule is an N-terminal RuvC-like domain nickase, e.g., the eaCas9 molecule comprises a mutation at N863, e.g., N863A.

In an embodiment, a single strand break is formed in the strand of the target nucleic acid to which the targeting domain of said gRNA is complementary. In another embodiment, a single strand break is formed in the strand of the target nucleic acid other than the strand to which the targeting domain of said gRNA is complementary.

In another aspect, disclosed herein is a nucleic acid, e.g., an isolated or non-naturally occurring nucleic acid, e.g., DNA, that comprises (a) a sequence that encodes a gRNA molecule comprising a targeting domain that is complementary with a target domain, e.g., with an SCD target position, in the HBB gene or BCL11A gene as disclosed herein.

In an embodiment, the nucleic acid encodes a gRNA molecule, e.g., a first gRNA molecule, comprising a targeting domain configured to provide a cleavage event, e.g., a double strand break or a single strand break, sufficiently close to an SCD target position in the HBB gene or BCL11A gene to allow alteration, e.g., alteration associated with HDR or NHEJ, of the an SCD target position in the HBB gene or BCL11A gene.

In an embodiment, the nucleic acid encodes a gRNA molecule, e.g., a first gRNA molecule, comprising a targeting domain configured to target an enzymatically inactive Cas9 (eiCas9) or an eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain), sufficiently close to an SCD knockdown target position to reduce, decrease or repress expression of the BCL11A gene.

In an embodiment, the nucleic acid encodes a gRNA molecule, e.g., the first gRNA molecule, comprising a targeting domain comprising a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any one of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. In an embodiment, the nucleic acid encodes a gRNA molecule comprising a targeting domain is selected from those in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31.

In an embodiment, the nucleic acid encodes a modular gRNA, e.g., one or more nucleic acids encode a modular gRNA. In another embodiment, the nucleic acid encodes a chimeric gRNA. The nucleic acid may encode a gRNA, e.g., the first gRNA molecule, comprising a targeting domain comprising 16 nucleotides or more in length. In one embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 16 nucleotides in length. In another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 17 nucleotides in length. In still another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 18 nucleotides in length. In still another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 19 nucleotides in length. In still another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 20 nucleotides in length. In still another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 21 nucleotides in length. In still another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 22 nucleotides in length. In still another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 23 nucleotides in length. In still another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 24 nucleotides in length. In still another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 25 nucleotides in length. In still another embodiment, the nucleic acid encodes a gRNA, e.g., the first gRNA molecule, comprising a targeting domain that is 26 nucleotides in length.

In an embodiment, the targeting domain comprises 16 nucleotides.

In an embodiment, the targeting domain comprises 17 nucleotides.

In an embodiment, the targeting domain comprises 18 nucleotides.

In an embodiment, the targeting domain comprises 19 nucleotides.

In an embodiment, the targeting domain comprises 20 nucleotides.

In an embodiment, the targeting domain comprises 21 nucleotides.

In an embodiment, the targeting domain comprises 22 nucleotides.

In an embodiment, the targeting domain comprises 23 nucleotides.

In an embodiment, the targeting domain comprises 24 nucleotides.

In an embodiment, the targeting domain comprises 25 nucleotides.

In an embodiment, the targeting domain comprises 26 nucleotides.

In an embodiment, a nucleic acid encodes a gRNA comprising from 5′ to 3′: a targeting domain (comprising a “core domain”, and optionally a “secondary domain”); a first complementarity domain; a linking domain; a second complementarity domain; a proximal domain; and a tail domain. In an embodiment, the proximal domain and tail domain are taken together as a single domain.

In an embodiment, a nucleic acid encodes a gRNA e.g., the first gRNA molecule, comprising a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 20 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, a nucleic acid encodes a gRNA e.g., the first gRNA molecule, comprising a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 30 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, a nucleic acid encodes a gRNA e.g., the first gRNA molecule, comprising a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 30 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, a nucleic acid encodes a gRNA comprising e.g., the first gRNA molecule, a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 40 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, a nucleic acid comprises (a) a sequence that encodes a gRNA molecule e.g., the first gRNA molecule, comprising a targeting domain that is complementary with a target domain in the HBB gene or BCL11A gene as disclosed herein, and further comprising (b) a sequence that encodes a Cas9 molecule.

The Cas9 molecule may be an enzymatically active Cas9 (eaCas9) molecule, e.g., an eaCas9 molecule that forms a double strand break in a target nucleic acid or an eaCas9 molecule forms a single strand break in a target nucleic acid (e.g., a nickase molecule). Alternatively, in an embodiment, the Cas9 molecule may be an enzymatically inactive Cas9 (eiCas9) molecule or a modified eiCas9 molecule, e.g., the eiCas9 molecule is fused to Krüppel-associated box (KRAB) to generate an eiCas9-KRAB fusion protein molecule.

A nucleic acid disclosed herein may comprise (a) a sequence that encodes a gRNA molecule comprising a targeting domain that is complementary with a target domain in the HBB gene or BCL11A gene as disclosed herein; (b) a sequence that encodes a Cas9 molecule; and further comprises (c)(i) a sequence that encodes a second gRNA molecule described herein having a targeting domain that is complementary to a second target domain of the HBB gene or BCL11A gene, and optionally, (c)(ii) a sequence that encodes a third gRNA molecule described herein having a targeting domain that is complementary to a third target domain of the HBB gene or BCL11A gene; and optionally, (c)(iii) a sequence that encodes a fourth gRNA molecule described herein having a targeting domain that is complementary to a fourth target domain of the HBB gene or BCL11A gene.

In an embodiment, a nucleic acid encodes a second gRNA molecule comprising a targeting domain configured to provide a cleavage event, e.g., a double strand break or a single strand break, sufficiently close to an SCD target position in the HBB gene or BCL11A gene, to allow alteration, e.g., alteration associated with HDR or NHEJ, of an SCD target position in the HBB gene or BCL11A gene, either alone or in combination with the break positioned by said first gRNA molecule.

In an embodiment, the nucleic acid encodes a second gRNA molecule comprising a targeting domain configured to target an enzymatically inactive Cas9 (eiCas9) or an eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain), sufficiently close to an SCD knockdown target position to reduce, decrease or repress expression of the BCL11A gene.

In an embodiment, a nucleic acid encodes a third gRNA molecule comprising a targeting domain configured to provide a cleavage event, e.g., a double strand break or a single strand break, sufficiently close to an SCD target position in the HBB gene or BCL11A gene to allow alteration, e.g., alteration associated with HDR or NHEJ, of an SCD target position in the HBB gene or BCL11A gene, either alone or in combination with the break positioned by the first and/or second gRNA molecule.

In an embodiment, the nucleic acid encodes a third gRNA molecule comprising a targeting domain configured to target an enzymatically inactive Cas9 (eiCas9) or an eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain), sufficiently close to an SCD knockdown target position to reduce, decrease or repress expression of the BCL11A gene.

In an embodiment, a nucleic acid encodes a fourth gRNA molecule comprising a targeting domain configured to provide a cleavage event, e.g., a double strand break or a single strand break, sufficiently close to an SCD target position in the HBB gene or BCL11A gene to allow alteration, e.g., alteration associated with HDR or NHEJ, of an SCD target position in the HBB gene or BCL11A gene, either alone or in combination with the break positioned by the first gRNA molecule, the second gRNA molecule and/or the third gRNA molecule.

In an embodiment, the nucleic acid encodes a fourth gRNA molecule comprising a targeting domain configured to target an enzymatically inactive Cas9 (eiCas9) or an eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain), sufficiently close to an SCD knockdown target position to reduce, decrease or repress expression of the BCL11A gene.

In an embodiment, the nucleic acid encodes a second gRNA molecule. The second gRNA is selected to target the same SCD target position as the first gRNA molecule. Optionally, the nucleic acid may encode a third gRNA, and further optionally, the nucleic acid may encode a fourth gRNA molecule. The third gRNA molecule and the fourth gRNA molecule are selected to target the same SCD target position as the first and/or second gRNA molecules.

In an embodiment, the nucleic acid encodes a second gRNA molecule comprising a targeting domain comprising a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from one of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. In an embodiment, the nucleic acid encodes a second gRNA molecule comprising a targeting domain selected from those in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. In an embodiment, when a third or fourth gRNA molecule are present, the third and fourth gRNA molecules may independently comprise a targeting domain comprising a sequence that is the same as, or differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from one of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. In a further embodiment, when a third or fourth gRNA molecule are present, the third and fourth gRNA molecules may independently comprise a targeting domain selected from those in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31.

In an embodiment, the nucleic acid encodes a second gRNA which is a modular gRNA, e.g., wherein one or more nucleic acid molecules encode a modular gRNA. In another embodiment, the nucleic acid encoding a second gRNA is a chimeric gRNA. In another embodiment, when a nucleic acid encodes a third or fourth gRNA, the third and/or fourth gRNA may be a modular gRNA or a chimeric gRNA. When multiple gRNAs are used, any combination of modular or chimeric gRNAs may be used.

A nucleic acid may encode a second, a third, and/or a fourth gRNA comprising a targeting domain comprising 16 nucleotides or more in length. In an embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 16 nucleotides in length. In another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 17 nucleotides in length. In still another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 18 nucleotides in length. In still another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 19 nucleotides in length. In still another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 20 nucleotides in length. In still another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 21 nucleotides in length. In still another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 22 nucleotides in length. In still another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 23 nucleotides in length. In still another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 24 nucleotides in length. In still another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 25 nucleotides in length. In still another embodiment, the nucleic acid encodes a second gRNA comprising a targeting domain that is 26 nucleotides in length.

In an embodiment, the targeting domain comprises 16 nucleotides.

In an embodiment, the targeting domain comprises 17 nucleotides.

In an embodiment, the targeting domain comprises 18 nucleotides.

In an embodiment, the targeting domain comprises 19 nucleotides.

In an embodiment, the targeting domain comprises 20 nucleotides.

In an embodiment, the targeting domain comprises 21 nucleotides.

In an embodiment, the targeting domain comprises 22 nucleotides.

In an embodiment, the targeting domain comprises 23 nucleotides.

In an embodiment, the targeting domain comprises 24 nucleotides.

In an embodiment, the targeting domain comprises 25 nucleotides.

In an embodiment, the targeting domain comprises 26 nucleotides.

In an embodiment, a nucleic acid encodes a second, a third, and/or a fourth gRNA comprising from 5′ to 3′: a targeting domain (comprising a “core domain”, and optionally a “secondary domain”); a first complementarity domain; a linking domain; a second complementarity domain; a proximal domain; and a tail domain. In an embodiment, the proximal domain and tail domain are taken together as a single domain.

In an embodiment, a nucleic acid encodes a second, a third, and/or a fourth gRNA comprising a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 20 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, a nucleic acid encodes a second, a third, and/or a fourth gRNA comprising a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 30 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, a nucleic acid encodes a second, a third, and/or a fourth gRNA comprising a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 35 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, a nucleic acid encodes a second, a third, and/or a fourth gRNA comprising a linking domain of no more than 25 nucleotides in length; a proximal and tail domain, that taken together, are at least 40 nucleotides in length; and a targeting domain equal to or greater than 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, when the HBB gene is corrected, e.g., by HDR, the nucleic acid encodes (a) a sequence that encodes a gRNA molecule comprising a targeting domain that is complementary with a target domain in the HBB gene as disclosed herein; (b) a sequence that encodes a Cas9 molecule; optionally, (c)(i) a sequence that encodes a second gRNA molecule described herein having a targeting domain that is complementary to a second target domain of the HBB gene, and further optionally, (c)(ii) a sequence that encodes a third gRNA molecule described herein having a targeting domain that is complementary to a third target domain of the HBB gene; and still further optionally, (c)(iii) a sequence that encodes a fourth gRNA molecule described herein having a targeting domain that is complementary to a fourth target domain of the HBB gene; and further may comprise (d) a template nucleic acid (in an embodiment where an exogenous template is used).

In an embodiment, a mutation in the HBB gene is corrected, e.g., by HDR, using an exogenously provided template nucleic acid.

In an embodiment, the template nucleic acid is a single stranded nucleic acid. In another embodiment, the template nucleic acid is a double stranded nucleic acid. In an embodiment, the template nucleic acid comprises a nucleotide sequence, e.g., of one or more nucleotides, that will be added to or will template a change in the target nucleic acid. In another embodiment, the template nucleic acid comprises a nucleotide sequence that may be used to modify the target position. In another embodiment, the template nucleic acid comprises a nucleotide sequence, e.g., of one or more nucleotides, that corresponds to wild type sequence of the target nucleic acid, e.g., of the target position.

The template nucleic acid may comprise a replacement sequence, e.g., a replacement sequence from the Table 27. In an embodiment, the template nucleic acid comprises a 5′ homology arm, e.g., a 5′ homology arm from Table 27. In another embodiment, the template nucleic acid comprises a 3′ homology arm, e.g., a 3′ homology arm from Table 27.

In another embodiment, a mutation in the HBB gene is corrected, e.g., by HDR, without using an exogenously provided template nucleic acid. While not wishing to be bound by theory, it is believed that an endogenous region of homology can mediate HDR-based correction. In an embodiment, alteration of the target sequence occurs by HDR with an endogenous genomic donor sequence. In an embodiment, the endogenous genomic donor sequence is located on the same chromosome as the target sequence. In another embodiment, the endogenous genomic donor sequence is located on a different chromosome from the target sequence. In an embodiment, the endogenous genomic donor sequence comprises one or more nucleotides derived from the HBD gene. Mutations in the HBB gene that can be corrected (e.g., altered) by HDR with an endogenous genomic donor sequence include, e.g., a point mutation at E6, e.g., E6V.

As described above, a nucleic acid may comprise (a) a sequence encoding a gRNA molecule comprising a targeting domain that is complementary with a target domain in the HBB gene or BCL11A gene, and (b) a sequence encoding a Cas9 molecule.

In an embodiment, (a) and (b) are present on the same nucleic acid molecule, e.g., the same vector, e.g., the same viral vector, e.g., the same adeno-associated virus (AAV) vector. In an embodiment, the nucleic acid molecule is an AAV vector. Exemplary AAV vectors that may be used in any of the described compositions and methods include an AAV2 vector, a modified AAV2 vector, an AAV3 vector, a modified AAV3 vector, an AAV6 vector, a modified AAV6 vector, an AAV8 vector and an AAV9 vector.

In another embodiment, (a) is present on a first nucleic acid molecule, e.g. a first vector, e.g., a first viral vector, e.g., a first AAV vector; and (b) is present on a second nucleic acid molecule, e.g., a second vector, e.g., a second vector, e.g., a second AAV vector. The first and second nucleic acid molecules may be AAV vectors.

In another embodiment, the nucleic acid may further comprise (c) a sequence that encodes a second, third and/or fourth gRNA molecule as described herein. In an embodiment, the nucleic acid comprises (a), (b) and (c). Each of (a) and (c) may be present on the same nucleic acid molecule, e.g., the same vector, e.g., the same viral vector, e.g., the same adeno-associated virus (AAV) vector. In an embodiment, the nucleic acid molecule is an AAV vector.

In another embodiment, (a) and (c) are on different vectors. For example, (a) may be present on a first nucleic acid molecule, e.g. a first vector, e.g., a first viral vector, e.g., a first AAV vector; and (c) may be present on a second nucleic acid molecule, e.g., a second vector, e.g., a second vector, e.g., a second AAV vector. In an embodiment, the first and second nucleic acid molecules are AAV vectors.

In another embodiment, each of (a), (b), and (c) are present on the same nucleic acid molecule, e.g., the same vector, e.g., the same viral vector, e.g., an AAV vector. In an embodiment, the nucleic acid molecule is an AAV vector. In an alternate embodiment, one of (a), (b), and (c) is encoded on a first nucleic acid molecule, e.g., a first vector, e.g., a first viral vector, e.g., a first AAV vector; and a second and third of (a), (b), and (c) is encoded on a second nucleic acid molecule, e.g., a second vector, e.g., a second vector, e.g., a second AAV vector. The first and second nucleic acid molecule may be AAV vectors.

In an embodiment, (a) is present on a first nucleic acid molecule, e.g., a first vector, e.g., a first viral vector, a first AAV vector; and (b) and (c) are present on a second nucleic acid molecule, e.g., a second vector, e.g., a second vector, e.g., a second AAV vector. The first and second nucleic acid molecule may be AAV vectors.

In another embodiment, (b) is present on a first nucleic acid molecule, e.g., a first vector, e.g., a first viral vector, e.g., a first AAV vector; and (a) and (c) are present on a second nucleic acid molecule, e.g., a second vector, e.g., a second vector, e.g., a second AAV vector. The first and second nucleic acid molecule may be AAV vectors.

In another embodiment, (c) is present on a first nucleic acid molecule, e.g., a first vector, e.g., a first viral vector, e.g., a first AAV vector; and (b) and (a) are present on a second nucleic acid molecule, e.g., a second vector, e.g., a second vector, e.g., a second AAV vector. The first and second nucleic acid molecule may be AAV vectors.

In another embodiment, each of (a), (b) and (c) are present on different nucleic acid molecules, e.g., different vectors, e.g., different viral vectors, e.g., different AAV vector. For example, (a) may be on a first nucleic acid molecule, (b) on a second nucleic acid molecule, and (c) on a third nucleic acid molecule. The first, second and third nucleic acid molecule may be AAV vectors.

In another embodiment, when a third and/or fourth gRNA molecule are present, each of (a), (b), (c)(i), (c)(ii) and (c)(iii) may be present on the same nucleic acid molecule, e.g., the same vector, e.g., the same viral vector, e.g., an AAV vector. In an embodiment, the nucleic acid molecule is an AAV vector. In an alternate embodiment, each of (a), (b), (c)(i), (c)(ii) and (c)(iii) may be present on the different nucleic acid molecules, e.g., different vectors, e.g., the different viral vectors, e.g., different AAV vectors. In further embodiments, each of (a), (b), (c)(i), (c)(ii) and (c)(iii) may be present on more than one nucleic acid molecule, but fewer than five nucleic acid molecules, e.g., AAV vectors.

In another embodiment, when (d) a template nucleic acid is present, each of (a), (b), and (d) may be present on the same nucleic acid molecule, e.g., the same vector, e.g., the same viral vector, e.g., an AAV vector. In an embodiment, the nucleic acid molecule is an AAV vector. In an alternate embodiment, each of (a), (b), and (d) may be present on the different nucleic acid molecules, e.g., different vectors, e.g., the different viral vectors, e.g., different AAV vectors. In further embodiments, each of (a), (b), and (d) may be present on more than one nucleic acid molecule, but fewer than three nucleic acid molecules, e.g., AAV vectors.

In another embodiment, when (d) a template nucleic acid is present, each of (a), (b), (c)(i) and (d) may be present on the same nucleic acid molecule, e.g., the same vector, e.g., the same viral vector, e.g., an AAV vector. In an embodiment, the nucleic acid molecule is an AAV vector. In an alternate embodiment, each of (a), (b), (c)(i) and (d) may be present on the different nucleic acid molecules, e.g., different vectors, e.g., the different viral vectors, e.g., different AAV vectors. In further embodiments, each of (a), (b), (c)(i) and (d) may be present on more than one nucleic acid molecule, but fewer than four nucleic acid molecules, e.g., AAV vectors.

In another embodiment, when (d) a template nucleic acid is present, each of (a), (b), (c)(i), (c)(ii) and (d) may be present on the same nucleic acid molecule, e.g., the same vector, e.g., the same viral vector, e.g., an AAV vector. In an embodiment, the nucleic acid molecule is an AAV vector. In an alternate embodiment, each of (a), (b), (c)(i), (c)(ii) and (d) may be present on the different nucleic acid molecules, e.g., different vectors, e.g., the different viral vectors, e.g., different AAV vectors. In further embodiments, each of (a), (b), (c)(i), (c)(ii) and (d) may be present on more than one nucleic acid molecule, but fewer than five nucleic acid molecules, e.g., AAV vectors.

In another embodiment, when (d) a template nucleic acid is present, each of (a), (b), (c)(i), (c)(ii), (c)(iii) and (d) may be present on the same nucleic acid molecule, e.g., the same vector, e.g., the same viral vector, e.g., an AAV vector. In an embodiment, the nucleic acid molecule is an AAV vector. In an alternate embodiment, each of (a), (b), (c)(i), (c)(ii), (c)(iii) and (d) may be present on the different nucleic acid molecules, e.g., different vectors, e.g., the different viral vectors, e.g., different AAV vectors. In further embodiments, each of (a), (b), (c)(i), (c)(ii), (c)(iii) and (d) may be present on more than one nucleic acid molecule, but fewer than six nucleic acid molecules, e.g., AAV vectors.

The nucleic acids described herein may comprise a promoter operably linked to the sequence that encodes the gRNA molecule of (a), e.g., a promoter described herein. The nucleic acid may further comprise a second promoter operably linked to the sequence that encodes the second, third and/or fourth gRNA molecule of (c), e.g., a promoter described herein. The promoter and second promoter differ from one another. In an embodiment, the promoter and second promoter are the same.

The nucleic acids described herein may further comprise a promoter operably linked to the sequence that encodes the Cas9 molecule of (b), e.g., a promoter described herein.

In another aspect, disclosed herein is a composition comprising (a) a gRNA molecule comprising a targeting domain that is complementary with a target domain in the HBB gene or BCL11A gene, as described herein. The composition of (a) may further comprise (b) a Cas9 molecule, e.g., a Cas9 molecule as described herein. A composition of (a) and (b) may further comprise (c) a second, third and/or fourth gRNA molecule, e.g., a second, third and/or fourth gRNA molecule described herein. A composition of (a), (b) and (c) may further comprise (d) a template nucleic acid (in an embodiment where an exogenous template is used). In an embodiment, the composition is a pharmaceutical composition. The Compositions described herein, e.g., pharmaceutical compositions described herein, can be used in treating SCD in a subject, e.g., in accordance with a method disclosed herein.

In another aspect, disclosed herein is a method of altering a cell, e.g., altering the structure, e.g., altering the sequence, of a target nucleic acid of a cell, comprising contacting said cell with: (a) a gRNA that targets the HBB gene or BCL11A gene, e.g., a gRNA as described herein; (b) a Cas9 molecule, e.g., a Cas9 molecule as described herein; and optionally, (c) a second, third and/or fourth gRNA that targets HBB gene or BCL11A gene, e.g., a gRNA; and optionally, (d) a template nucleic acid, as described herein.

In an embodiment, the method comprises contacting said cell with (a) and (b).

In an embodiment, the method comprises contacting said cell with (a), (b), and (c).

In an embodiment, the method comprises contacting said cell with (a), (b), (c) and (d).

In an embodiment, the gRNA targets the HBB gene and no exogenous template nucleic acid is contacted with the cell.

The gRNA of (a) and optionally (c) may be selected from any of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, or a gRNA that differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31.

In an embodiment, the method comprises contacting a cell from a subject suffering from or likely to develop SCD. The cell may be from a subject having a mutation at an SCD target position in the HBB gene or a subject which would benefit from having a mutation at an SCD target position in the BCL11A gene.

In an embodiment, the cell being contacted in the disclosed method is an erythroid cell. The contacting may be performed ex vivo and the contacted cell may be returned to the subject's body after the contacting step. In another embodiment, the contacting step may be performed in vivo.

In an embodiment, the method of altering a cell as described herein comprises acquiring knowledge of the sequence at an SCD target position in said cell, prior to the contacting step. Acquiring knowledge of the sequence at an SCD target position in the cell may be by sequencing the HBB gene or BCL11A gene, or a portion of the HBB gene or BCL11A gene.

In an embodiment, the contacting step of the method comprises contacting the cell with a nucleic acid, e.g., a vector, e.g., an AAV vector, that expresses at least one of (a), (b), and (c). In an embodiment, the contacting step of the method comprises contacting the cell with a nucleic acid, e.g., a vector, e.g., an AAV vector, that expresses each of (a), (b), and (c). In another embodiment, the contacting step of the method comprises delivering to the cell a Cas9 molecule of (b) and a nucleic acid which encodes a gRNA (a) and optionally, a second gRNA (c)(i) (and further optionally, a third gRNA (c)(iv) and/or fourth gRNA (c)(iii).

In an embodiment, the contacting step of the method comprises contacting the cell with a nucleic acid, e.g., a vector, e.g., an AAV vector, that expresses at least one of (a), (b), (c) and (d). In an embodiment, the contacting step of the method comprises contacting the cell with a nucleic acid, e.g., a vector, e.g., an AAV vector, that expresses each of (a), (b), and (c). In another embodiment, the contacting step of the method comprises delivering to the cell a Cas9 molecule of (b), a nucleic acid which encodes a gRNA of (a) and a template nucleic acid of (d), and optionally, a second gRNA (c)(i) (and further optionally, a third gRNA (c)(iv) and/or fourth gRNA (c)(iii).

In an embodiment, contacting comprises contacting the cell with a nucleic acid, e.g., a vector, e.g., an AAV vector, e.g., an AAV2 vector, a modified AAV2 vector, an AAV3 vector, a modified AAV3 vector, an AAV6 vector, a modified AAV6 vector, an AAV8 vector or an AAV9 vector.

In an embodiment, contacting comprises delivering to the cell a Cas9 molecule of (b), as a protein or an mRNA, and a nucleic acid which encodes (a) and optionally a second, third and/or fourth gRNA of (c).

In an embodiment, contacting comprises delivering to the cell a Cas9 molecule of (b), as a protein or an mRNA, said gRNA of (a), as an RNA, and optionally said second, third and/or fourth gRNA of (c), as an RNA.

In an embodiment, contacting comprises delivering to the cell a gRNA of (a) as an RNA, optionally said second, third and/or fourth gRNA of (c) as an RNA, and a nucleic acid that encodes the Cas9 molecule of (b).

In another aspect, disclosed herein is a method of treating or preventing a subject suffering from or likely to develop SCD, e.g., altering the structure, e.g., sequence, of a target nucleic acid of the subject, comprising contacting the subject (or a cell from the subject) with:

(a) a gRNA that targets the HBB gene or BCL11A gene, e.g., a gRNA disclosed herein;

(b) a Cas9 molecule, e.g., a Cas9 molecule disclosed herein; and

optionally, (c)(i) a second gRNA that targets the HBB gene or BCL11A gene, e.g., a second gRNA disclosed herein, and

further optionally, (c)(ii) a third gRNA, and still further optionally, (c)(iii) a fourth gRNA that target the HBB gene or BCL11A gene, e.g., a third and fourth gRNA disclosed herein.

The method of treating a subject may further comprise contacting the subject (or a cell from the subject) with (d) a template nucleic acid (in an embodiment where an exogenous template is used), e.g., a template nucleic acid disclosed herein.

In an embodiment, a template nucleic acid is used when the method of treating a subject uses HDR to alter the sequence of the target nucleic acid of the subject. In an embodiment, the gRNA targets the HBB gene and no exogenous template nucleic acid is contacted with the subject (or a cell from the subject).

In an embodiment, contacting comprises contacting with (a) and (b).

In an embodiment, contacting comprises contacting with (a), (b), and (c)(i).

In an embodiment, contacting comprises contacting with (a), (b), (c)(i) and (c)(ii).

In an embodiment, contacting comprises contacting with (a), (b), (c)(i), (c)(ii) and (c)(iii).

In an embodiment, contacting comprises contacting with (a), (b), (c)(i) and (d).

In an embodiment, contacting comprises contacting with (a), (b), (c)(i), (c)(ii) and (d).

In an embodiment, contacting comprises contacting with (a), (b), (c)(i), (c)(ii), (c)(iii) and (d).

The gRNA of (a) or (c) (e.g., (c)(i), (c)(ii), or (c)(iii) may be selected from any of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, or a gRNA that differs by no more than 1, 2, 3, 4, or 5 nucleotides from, a targeting domain sequence from any of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31.

In an embodiment, the method comprises acquiring knowledge of the sequence (e.g., a mutation) of an SCD target position in said subject.

In an embodiment, the method comprises acquiring knowledge of the sequence (e.g., a mutation) of an SCD target position in said subject by sequencing the HBB gene or BCL11A gene or a portion of the HBB gene or BCL11A gene.

In an embodiment, the method comprises correcting a mutation at an SCD target position in the HBB gene.

In an embodiment, the method comprises correcting a mutation at an SCD target position in the HBB gene by HDR.

In an embodiment, the method comprises introducing a mutation at an SCD target position in the BCL11A gene.

In an embodiment, the method comprises introducing a mutation at an SCD target position in the BCL11A gene by NHEJ.

When the method comprises correcting the mutation at an SCD target position by HDR, a Cas9 of (b), at least one guide RNA, e.g., a guide RNA of (a) and a template nucleic acid of (d) are included in the contacting step.

In an embodiment, a cell of the subject is contacted ex vivo with (a), (b), (d) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii). In an embodiment, said cell is returned to the subject's body.

In an embodiment, a cell of the subject is contacted is in vivo with (a), (b) (d) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, the cell of the subject is contacted in vivo by intravenous delivery of (a), (b), (d) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, the cell of the subject is contacted in vivo by intramuscular delivery of (a), (b), (d) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, the cell of the subject is contacted in vivo by subcutaneous delivery of (a), (b), (d) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, the cell of the subject is contacted in vivo by intra-bone marrow (IBM) delivery of (a), (b), (d) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, contacting comprises contacting the subject with a nucleic acid, e.g., a vector, e.g., an AAV vector, described herein, e.g., a nucleic acid that encodes at least one of (a), (b), (d) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, contacting comprises delivering to said subject said Cas9 molecule of (b), as a protein or mRNA, and a nucleic acid which encodes (a), a nucleic acid of (d) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, contacting comprises delivering to the subject the Cas9 molecule of (b), as a protein or mRNA, the gRNA of (a), as an RNA, a nucleic acid of (d) and optionally the second, third and/or fourth gRNA of (c), as an RNA.

In an embodiment, contacting comprises delivering to the subject the gRNA of (a), as an RNA, optionally said second, third and/or fourth gRNA of (c), as an RNA, a nucleic acid that encodes the Cas9 molecule of (b), and a nucleic acid of (d).

When the method comprises (1) introducing a mutation at an SCD target position by NHEJ or (2) knocking down expression of the BCL11A gene by targeting the promoter region, a Cas9 of (b) and at least one guide RNA, e.g., a guide RNA of (a) are included in the contacting step.

In an embodiment, a cell of the subject is contacted ex vivo with (a), (b) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii). In an embodiment, said cell is returned to the subject's body.

In an embodiment, a populations of cells from a subject is contacted ex vivo with (a), (b) and optionally (c) to correct the E6V mutation in the HBB gene and a second population of cells from the subject is contacted ex vivo with (a), (b) and optionally (c) to introduce a mutation in the BCL11A gene to knockout the BCL11A gene. A mixture of the two cell populations may be returned to the subject's body to treat or prevent SCD.

In an embodiment, a cell of the subject is contacted is in vivo with (a), (b) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii). In an embodiment, the cell of the subject is contacted in vivo by intravenous delivery of (a), (b) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii). In an embodiment, the cell of the subject is contacted in vivo by intramuscular delivery of (a), (b) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii). In an embodiment, the cell of the subject is contacted in vivo by subcutaneous delivery of (a), (b) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii). In an embodiment, the cell of the subject is contacted in vivo by intra-bone marrow (IBM) delivery of (a), (b) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, contacting comprises contacting the subject with a nucleic acid, e.g., a vector, e.g., an AAV vector, described herein, e.g., a nucleic acid that encodes at least one of (a), (b), and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, contacting comprises delivering to said subject said Cas9 molecule of (b), as a protein or mRNA, and a nucleic acid which encodes (a) and optionally (c)(i), further optionally (c)(ii), and still further optionally (c)(iii).

In an embodiment, contacting comprises delivering to the subject the Cas9 molecule of (b), as a protein or mRNA, the gRNA of (a), as an RNA, and optionally the second, third and/or fourth gRNA of (c), as an RNA.

In an embodiment, contacting comprises delivering to the subject the gRNA of (a), as an RNA, optionally said second, third and/or fourth gRNA of (c), as an RNA, and a nucleic acid that encodes the Cas9 molecule of (b).

In another aspect, disclosed herein is a reaction mixture comprising a gRNA, a nucleic acid, or a composition described herein, and a cell, e.g., a cell from a subject having, or likely to develop SCD, or a subject having a mutation at an SCD target position in the HBB gene, or a cell from a subject which would benefit from having a mutation at an SCD target position in the BCL11A gene.

In another aspect, disclosed herein is a kit comprising, (a) gRNA molecule described herein, or nucleic acid that encodes the gRNA, and one or more of the following:

(b) a Cas9 molecule, e.g., a Cas9 molecule described herein, or a nucleic acid or mRNA that encodes the Cas9;

(c)(i) a second gRNA molecule, e.g., a second gRNA molecule described herein or a nucleic acid that encodes (c)(i);

(c)(ii) a third gRNA molecule, e.g., a second gRNA molecule described herein or a nucleic acid that encodes (c)(ii);

(c)(iii) a fourth gRNA molecule, e.g., a second gRNA molecule described herein or a nucleic acid that encodes (c)(iii);

(d) a template nucleic acid (in an embodiment where an exogenous template is used), e.g., a template nucleic acid described herein.

In an embodiment, the kit comprises nucleic acid, e.g., an AAV vector, that encodes one or more of (a), (b), (c)(i), (c)(ii), (c)(iii) and (d).

In an aspect, the disclosure features a gRNA molecule, referred to herein as a governing gRNA molecule, comprising a targeting domain which is complementary to a target domain on a nucleic acid that encodes a component of the CRISPR/Cas system introduced into a cell or subject. In an embodiment, the governing gRNA molecule targets a nucleic acid that encodes a Cas9 molecule or a nucleic acid that encodes a target gene gRNA molecule. In an embodiment, the governing gRNA comprises a targeting domain that is complementary to a target domain in a sequence that encodes a Cas9 component, e.g., a Cas9 molecule or target gene gRNA molecule. In an embodiment, the target domain is designed with, or has, minimal homology to other nucleic acid sequences in the cell, e.g., to minimize off-target cleavage. For example, the targeting domain on the governing gRNA can be selected to reduce or minimize off-target effects. In an embodiment, a target domain for a governing gRNA can be disposed in the control or coding region of a Cas9 molecule or disposed between a control region and a transcribed region. In an embodiment, a target domain for a governing gRNA can be disposed in the control or coding region of a target gene gRNA molecule or disposed between a control region and a transcribed region for a target gene gRNA. While not wishing to be bound by theory, it is believed that altering, e.g., inactivating, a nucleic acid that encodes a Cas9 molecule or a nucleic acid that encodes a target gene gRNA molecule can be effected by cleavage of the targeted nucleic acid sequence or by binding of a Cas9 molecule/governing gRNA molecule complex to the targeted nucleic acid sequence.

The compositions, reaction mixtures and kits, as disclosed herein, can also include a governing gRNA molecule, e.g., a governing gRNA molecule disclosed herein.

Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, suitable methods and materials are described below. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety. In addition, the materials, methods, and examples are illustrative only and not intended to be limiting.

Headings, including numeric and alphabetical headings and subheadings, are for organization and presentation and are not intended to be limiting.

Other features and advantages of the invention will be apparent from the detailed description, drawings, and from the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1I are representations of several exemplary gRNAs.

FIG. 1A depicts a modular gRNA molecule derived in part (or modeled on a sequence in part) from Streptococcus pyogenes (S. pyogenes) as a duplexed structure (SEQ ID NOS: 42 and 43, respectively, in order of appearance);

FIG. 1B depicts a unimolecular (or chimeric) gRNA molecule derived in part from S. pyogenes as a duplexed structure (SEQ ID NO: 44);

FIG. 1C depicts a unimolecular gRNA molecule derived in part from S. pyogenes as a duplexed structure (SEQ ID NO: 45);

FIG. 1D depicts a unimolecular gRNA molecule derived in part from S. pyogenes as a duplexed structure (SEQ ID NO: 46);

FIG. 1E depicts a unimolecular gRNA molecule derived in part from S. pyogenes as a duplexed structure (SEQ ID NO: 47);

FIG. 1F depicts a modular gRNA molecule derived in part from Streptococcus thermophilus (S. thermophilus) as a duplexed structure (SEQ ID NOS: 48 and 49, respectively, in order of appearance);

FIG. 1G depicts an alignment of modular gRNA molecules of S. pyogenes and S. thermophilus (SEQ ID NOS: 50-53, respectively, in order of appearance).

FIGS. 1H-1I depicts additional exemplary structures of unimolecular gRNA molecules.

FIG. 1H shows an exemplary structure of a unimolecular gRNA molecule derived in part from S. pyogenes as a duplexed structure (SEQ ID NO: 45).

FIG. 11 shows an exemplary structure of a unimolecular gRNA molecule derived in part from S. aureus as a duplexed structure (SEQ ID NO: 40).

FIGS. 2A-2G depict an alignment of Cas9 sequences from Chylinski et al. (RNA Biol. 2013; 10(5): 726-737). The N-terminal RuvC-like domain is boxed and indicated with a “Y”. The other two RuvC-like domains are boxed and indicated with a “B”. The HNH-like domain is boxed and indicated by a “G”. Sm: S. mutans (SEQ ID NO: 1); Sp: S. pyogenes (SEQ ID NO: 2); St: S. thermophilus (SEQ ID NO: 3); Li: L. innocua (SEQ ID NO: 4). Motif: this is a motif based on the four sequences: residues conserved in all four sequences are indicated by single letter amino acid abbreviation; “*” indicates any amino acid found in the corresponding position of any of the four sequences; and “-” indicates any amino acid, e.g., any of the 20 naturally occurring amino acids, or absent.

FIGS. 3A-3B show an alignment of the N-terminal RuvC-like domain from the Cas9 molecules disclosed in Chylinski et al (SEQ ID NOS: 54-103, respectively, in order of appearance). The last line of FIG. 3B identifies 4 highly conserved residues.

FIGS. 4A-4B show an alignment of the N-terminal RuvC-like domain from the Cas9 molecules disclosed in Chylinski et al. with sequence outliers removed (SEQ ID NOS: 104-177, respectively, in order of appearance). The last line of FIG. 4B identifies 3 highly conserved residues.

FIGS. 5A-5C show an alignment of the HNH-like domain from the Cas9 molecules disclosed in Chylinski et al (SEQ ID NOS: 178-252, respectively, in order of appearance). The last line of FIG. 5C identifies conserved residues.

FIGS. 6A-6B show an alignment of the HNH-like domain from the Cas9 molecules disclosed in Chylinski et al. with sequence outliers removed (SEQ ID NOS: 253-302, respectively, in order of appearance). The last line of FIG. 6B identifies 3 highly conserved residues.

FIGS. 7A-7B depict an alignment of Cas9 sequences from S. pyogenes and Neisseria meningitidis (N. meningitidis). The N-terminal RuvC-like domain is boxed and indicated with a “Y”. The other two RuvC-like domains are boxed and indicated with a “B”. The HNH-like domain is boxed and indicated with a “G”. Sp: S. pyogenes; Nm: N. meningitidis. Motif: this is a motif based on the two sequences: residues conserved in both sequences are indicated by a single amino acid designation; “*” indicates any amino acid found in the corresponding position of any of the two sequences; “-” indicates any amino acid, e.g., any of the 20 naturally occurring amino acids, and “-” indicates any amino acid, e.g., any of the 20 naturally occurring amino acids, or absent.

FIG. 8 shows a nucleic acid sequence encoding Cas9 of N. meningitidis (SEQ ID NO: 303). Sequence indicated by an “R” is an SV40 NLS; sequence indicated as “G” is an HA tag; and sequence indicated by an “O” is a synthetic NLS sequence; the remaining (unmarked) sequence is the open reading frame (ORF).

FIGS. 9A and 9B are schematic representations of the domain organization of S. pyogenes Cas 9. FIG. 9A shows the organization of the Cas9 domains, including amino acid positions, in reference to the two lobes of Cas9 (recognition (REC) and nuclease (NUC) lobes). FIG. 9B shows the percent homology of each domain across 83 Cas9 orthologs.

FIG. 10 shows chromosome 2 location (according to UCSC Genome Browser hg 19 human genome assembly) that corresponds to BCL11A intron 2. Three erythroid DHSs are labeled as distance in kilobases from BCL11A TSS (+62, +58 and +55). BCL11A transcription is from right to left.

FIG. 11 depicts the efficiency of NHEJ mediated by a Cas9 molecule and exemplary gRNA molecules targeting three different regions of the BCL11A locus.

FIGS. 12A-12B depict detected deletion events resulting from co-transfection of exemplary gRNA molecules, BCL11A-2983W and BCL11A-2981W.

FIG. 12A depicts schematic of DNA sequence recognized by BCL11A-2983W and BCL11A-2981W, which flanks the putative erythroid enhancer elements.

FIG. 12B depicts sequenced deletion events from the TOPO cloning of the PCR using primers that flank the enhancer region. A product is obtained when a deletion event has taken place.

FIGS. 13A-13B depicts detected deletion events resulting from co-transfection of the exemplary gRNA molecules, BCL11A-2995W and BCL11A-2984W.

FIG. 13A depicts Schematic of DNA sequence recognized by BCL11A-2995W and BCL11A-2984W, which flanks the putative erythroid enhancer elements.

FIG. 13B depicts sequenced deletion events from the TOPO cloning of the PCR using primers that flank the enhancer region. A product is obtained when a deletion event has taken place.

FIG. 14 depicts a scheme of the pair 8/15 of gRNAs surrounding the sickle mutation in combination with a Cas9 nickase (D10A or N863A). The nickases are shown as the grey ovals.

FIG. 15 depicts the percentages of total editing event after a wildtype Cas9 or a Cas9 nickase (D10A or N863A). A preprentation of at least three independent experiments for each condition is shown.

FIG. 16A depicts the frequency of deletions a wildtype Cas9 or a Cas9 nickase (D10A or N863A). A representation of at least 3 independent experiments for each condition is shown.

FIG. 16B depicts the frequency distribution of the length of deletions using a wildtype Cas9 and gRNA 8 (similar results have been obtained with gRNA 15).

FIG. 16C depicts the frequency distribution of the length of deletions using a Cas9 nickase (D10A) with gRNAs 8/15 (similar results have been obtained using Cas9 N863A).

FIG. 17A depicts the frequency of gene conversion a wildtype Cas9 or a Cas9 nickase (D10A or N863A).

FIG. 17B shows a scheme representing the region of similarity between the HBB and HBD loci.

FIG. 18 depicts the frequency of different lengths of HBD sequences that were incorporated into the HBB locus.

FIG. 19A depicts the frequency of insertions using a wildtype Cas9 or a Cas9 nickase (D10A or N863A). A representation of at least three independent experiments for each condition is shown.

FIG. 19B depicts examples of common reads observed in U2OS cells electroporated with plasmid encoding Cas9 N863 and gRNA 8/15 pair. The HBB reference is shown on the top.

FIG. 20A is a schematic representation of the donor template.

FIG. 20B depicts the frequency of HDR using a wildtype Cas9 or a Cas9 nickase (D10A or N863A).

FIG. 20C depicts different forms of nonors and there contribution to HDR.

FIG. 21 depicts genome editing of the HBB locus in bone marrow leukemia K562 hematopoietic cells after electroporation of Cas9 protein complexed to HBB gRNAs 8 and 15 (RNP) or Cas9 mRNA co-delivered with HBB gRNAs 8 and 15 (RNA).

DETAILED DESCRIPTION Definitions

“Alt-HDR” or “alternative HDR”, or alternative homology-directed repair, as used herein, refers to the process of repairing DNA damage using a homologous nucleic acid (e.g., an endogenous homologous sequence, e.g., a sister chromatid, or an exogenous nucleic acid, e.g., a template nucleic acid). Alt-HDR is distinct from canonical HDR in that the process utilizes different pathways from canonical HDR, and can be inhibited by the canonical HDR mediators, RAD51 and BRCA2. Also, alt-HDR uses a single-stranded or nicked homologous nucleic acid for repair of the break.

“Canonical HDR”, or canonical homology-directed repair, as used herein, refers to the process of repairing DNA damage using a homologous nucleic acid (e.g., an endogenous homologous sequence, e.g., a sister chromatid, or an exogenous nucleic acid, e.g., a template nucleic acid). Canonical HDR typically acts when there has been significant resection at the double strand break, forming at least one single stranded portion of DNA. In a normal cell, HDR typically involves a series of steps such as recognition of the break, stabilization of the break, resection, stabilization of single stranded DNA, formation of a DNA crossover intermediate, resolution of the crossover intermediate, and ligation. The process requires RAD51 and BRCA2, and the homologous nucleic acid is typically double-stranded.

Unless indicated otherwise, the term “HDR” as used herein encompasses canonical HDR and alt-HDR.

“Domain”, as used herein, is used to describe segments of a protein or nucleic acid. Unless otherwise indicated, a domain is not required to have any specific functional property.

Calculations of homology or sequence identity between two sequences (the terms are used interchangeably herein) are performed as follows. The sequences are aligned for optimal comparison purposes (e.g., gaps can be introduced in one or both of a first and a second amino acid or nucleic acid sequence for optimal alignment and non-homologous sequences can be disregarded for comparison purposes). The optimal alignment is determined as the best score using the GAP program in the GCG software package with a Blossum 62 scoring matrix with a gap penalty of 12, a gap extend penalty of 4, and a frame shift gap penalty of 5. The amino acid residues or nucleotides at corresponding amino acid positions or nucleotide positions are then compared. When a position in the first sequence is occupied by the same amino acid residue or nucleotide as the corresponding position in the second sequence, then the molecules are identical at that position. The percent identity between the two sequences is a function of the number of identical positions shared by the sequences.

“Governing gRNA molecule”, as used herein, refers to a gRNA molecule that comprises a targeting domain that is complementary to a target domain on a nucleic acid that comprises a sequence that encodes a component of the CRISPR/Cas system that is introduced into a cell or subject. A governing gRNA does not target an endogenous cell or subject sequence. In an embodiment, a governing gRNA molecule comprises a targeting domain that is complementary with a target sequence on: (a) a nucleic acid that encodes a Cas9 molecule; (b) a nucleic acid that encodes a gRNA which comprises a targeting domain that targets the HBB or BCL11A gene (a target gene gRNA); or on more than one nucleic acid that encodes a CRISPR/Cas component, e.g., both (a) and (b). In an embodiment, a nucleic acid molecule that encodes a CRISPR/Cas component, e.g., that encodes a Cas9 molecule or a target gene gRNA, comprises more than one target domain that is complementary with a governing gRNA targeting domain. While not wishing to be bound by theory, it is believed that a governing gRNA molecule complexes with a Cas9 molecule and results in Cas9 mediated inactivation of the targeted nucleic acid, e.g., by cleavage or by binding to the nucleic acid, and results in cessation or reduction of the production of a CRISPR/Cas system component. In an embodiment, the Cas9 molecule forms two complexes: a complex comprising a Cas9 molecule with a target gene gRNA, which complex will alter the HBB or BCL11A gene; and a complex comprising a Cas9 molecule with a governing gRNA molecule, which complex will act to prevent further production of a CRISPR/Cas system component, e.g., a Cas9 molecule or a target gene gRNA molecule. In an embodiment, a governing gRNA molecule/Cas9 molecule complex binds to or promotes cleavage of a control region sequence, e.g., a promoter, operably linked to a sequence that encodes a Cas9 molecule, a sequence that encodes a transcribed region, an exon, or an intron, for the Cas9 molecule. In an embodiment, a governing gRNA molecule/Cas9 molecule complex binds to or promotes cleavage of a control region sequence, e.g., a promoter, operably linked to a gRNA molecule, or a sequence that encodes the gRNA molecule. In an embodiment, the governing gRNA, e.g., a Cas9-targeting governing gRNA molecule, or a target gene gRNA-targeting governing gRNA molecule, limits the effect of the Cas9 molecule/target gene gRNA molecule complex-mediated gene targeting. In an embodiment, a governing gRNA places temporal, level of expression, or other limits, on activity of the Cas9 molecule/target gene gRNA molecule complex. In an embodiment, a governing gRNA reduces off-target or other unwanted activity. In an embodiment, a governing gRNA molecule inhibits, e.g., entirely or substantially entirely inhibits, the production of a component of the Cas9 system and thereby limits, or governs, its activity.

“Modulator”, as used herein, refers to an entity, e.g., a drug, that can alter the activity (e.g., enzymatic activity, transcriptional activity, or translational activity), amount, distribution, or structure of a subject molecule or genetic sequence. In an embodiment, modulation comprises cleavage, e.g., breaking of a covalent or non-covalent bond, or the forming of a covalent or non-covalent bond, e.g., the attachment of a moiety, to the subject molecule. In an embodiment, a modulator alters the, three dimensional, secondary, tertiary, or quaternary structure, of a subject molecule. A modulator can increase, decrease, initiate, or eliminate a subject activity.

“Large molecule”, as used herein, refers to a molecule having a molecular weight of at least 2, 3, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, or 100 kD. Large molecules include proteins, polypeptides, nucleic acids, biologics, and carbohydrates.

A “polypeptide”, as used herein, refers to a polymer of amino acids having less than 100 amino acid residues. In an embodiment, it has less than 50, 20, or 10 amino acid residues.

“Non-homologous end joining” or “NHEJ”, as used herein, refers to ligation mediated repair and/or non-template mediated repair including canonical NHEJ (cNHEJ), alternative NHEJ (altNHEJ), microhomology-mediated end joining (MMEJ), single-strand annealing (SSA), and synthesis-dependent microhomology-mediated end joining (SD-MMEJ).

A “reference molecule”, e.g., a reference Cas9 molecule or reference gRNA, as used herein, refers to a molecule to which a subject molecule, e.g., a subject Cas9 molecule of subject gRNA molecule, e.g., a modified or candidate Cas9 molecule is compared. For example, a Cas9 molecule can be characterized as having no more than 10% of the nuclease activity of a reference Cas9 molecule. Examples of reference Cas9 molecules include naturally occurring unmodified Cas9 molecules, e.g., a naturally occurring Cas9 molecule such as a Cas9 molecule of S. pyogenes, S. aureus or S. thermophilus. In an embodiment, the reference Cas9 molecule is the naturally occurring Cas9 molecule having the closest sequence identity or homology with the Cas9 molecule to which it is being compared. In an embodiment, the reference Cas9 molecule is a sequence, e.g., a naturally occurring or known sequence, which is the parental form on which a change, e.g., a mutation has been made.

“Replacement”, or “replaced”, as used herein with reference to a modification of a molecule does not require a process limitation but merely indicates that the replacement entity is present.

“Small molecule”, as used herein, refers to a compound having a molecular weight less than about 2 kD, e.g., less than about 2 kD, less than about 1.5 kD, less than about 1 kD, or less than about 0.75 kD.

“Subject”, as used herein, may mean either a human or non-human animal. The term includes, but is not limited to, mammals (e.g., humans, other primates, pigs, rodents (e.g., mice and rats or hamsters), rabbits, guinea pigs, cows, horses, cats, dogs, sheep, and goats). In an embodiment, the subject is a human. In another embodiment, the subject is poultry.

“Treat”, “treating” and “treatment”, as used herein, mean the treatment of a disease in a mammal, e.g., in a human, including (a) inhibiting the disease, i.e., arresting or preventing its development; (b) relieving the disease, i.e., causing regression of the disease state; and (c) curing the disease.

“Prevent”, “preventing” and “prevention”, as used herein, means the prevention of a disease in a mammal, e.g., in a human, including (a) avoiding or precluding the disease; (2) affecting the predisposition toward the disease, e.g., preventing at least one symptom of the disease or to delay onset of at least one symptom of the disease.

“X” as used herein in the context of an amino acid sequence, refers to any amino acid (e.g., any of the twenty natural amino acids) unless otherwise specified.

Methods of Repairing Mutation(s) in the HBB Gene

One approach to treat or prevent SCD is to repair (i.e., correct) one or more mutations in the HBB gene, e.g., by HDR. In this approach, mutant HBB allele(s) are corrected and restored to wild type state. While not wishing to be bound by theory, it is believed that correction of the glutamic acid to valine substitution at amino acid 6 in the beta-globin gene restores wild type beta-globin production within erythroid cells. The method described herein can be performed in all cell types. Beta-globin is expressed in cells of erythroid cell lineage. In an embodiment, an erythroid cell is targeted.

In an embodiment, one HBB allele is repaired in the subject. In another embodiment, both HBB alleles are repaired in the subject. In either situation, the subject can be cured of disease. As the disease only displays a phenotype when both alleles are mutated, repair of a single allele is adequate for a cure.

In one aspect, methods and compositions discussed herein, provide for the correction of the underlying genetic cause of SCD, e.g., the correction of a mutation at a target position in the HBB gene, e.g., correction of a mutation at amino acid position 6, e.g., an E6V substitution in the HBB gene.

In an embodiment, the method provides for the correction of a mutation at a target position in the HBB gene, e.g., correction of a mutation at amino acid position 6, e.g., an E6V substitution in the HBB gene. As described herein, in one embodiment, the method comprises the introduction of one or more breaks (e.g., single strand breaks or double strand breaks) sufficiently close to (e.g., either 5′ or 3′ to) the target position in the HBB gene, e.g., E6V.

In an embodiment, the targeting domain of the gRNA molecule is configured to provide a cleavage event, e.g., a double strand break or a single strand break, sufficiently close to (e.g., either 5′ or 3′ to) the target position in the HBB gene, e.g., E6V to allow correction, e.g., an alteration in the HBB gene, e.g., an alternation associated with HDR. In an embodiment, the targeting domain is configured such that a cleavage event, e.g., a double strand or single strand break, is positioned within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of a the target position in the HBB gene, e.g., E6V. The break, e.g., a double strand or single strand break, can be positioned upstream or downstream of the target position in the HBB gene, e.g., E6V.

In an embodiment, a second, third and/or fourth gRNA molecule is configured to provide a cleavage event, e.g., a double strand break or a single strand break, sufficiently close to (e.g., either 5′ or 3′ to) the target position in the HBB gene, e.g., E6V to allow correction, e.g., an alteration associated with HDR in the HBB gene. In an embodiment, the targeting domain is configured such that a cleavage event, e.g., a double strand or single strand break, is positioned within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of a the target position in the HBB gene, e.g., E6V. The break, e.g., a double strand or single strand break, can be positioned upstream or downstream of the target position in the HBB gene, e.g., E6V.

In an embodiment, a single strand break is accompanied by an additional single strand break, positioned by a second, third and/or fourth gRNA molecule, as discussed below. For example, The targeting domains bind configured such that a cleavage event, e.g., the two single strand breaks, are positioned within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position in the HBB gene, e.g., E6V. In an embodiment, the first and second gRNA molecules are configured such, that when guiding a Cas9 nickase, a single strand break will be accompanied by an additional single strand break, positioned by a second gRNA, sufficiently close to one another to result in an alteration of the target position in the HBB gene, e.g., E6V. In an embodiment, the first and second gRNA molecules are configured such that a single strand break positioned by said second gRNA is within 10, 20, 30, 40, or 50 nucleotides of the break positioned by said first gRNA molecule, e.g., when the Cas9 is a nickase. In an embodiment, the two gRNA molecules are configured to position cuts at the same position, or within a few nucleotides of one another, on different strands, e.g., essentially mimicking a double strand break.

In an embodiment, a double strand break can be accompanied by an additional double strand break, positioned by a second, third and/or fourth gRNA molecule, as is discussed below. For example, the targeting domain of a first gRNA molecule is configured such that a double strand break is positioned upstream of the target position in the HBB gene, e.g., E6V, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position; and the targeting domain of a second gRNA molecule is configured such that a double strand break is positioned downstream the target position in the HBB gene, e.g., E6V, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position.

In an embodiment, a double strand break can be accompanied by two additional single strand breaks, positioned by a second gRNA molecule and a third gRNA molecule. For example, the targeting domain of a first gRNA molecule is configured such that a double strand break is positioned upstream of the target position in the HBB gene, e.g., E6V, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position; and the targeting domains of a second and third gRNA molecule are configured such that two single strand breaks are positioned downstream of the target position in the HBB gene, e.g., E6V, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position. In an embodiment, the targeting domain of the first, second and third gRNA molecules are configured such that a cleavage event, e.g., a double strand or single strand break, is positioned, independently for each of the gRNA molecules.

In an embodiment, a first and second single strand breaks can be accompanied by two additional single strand breaks positioned by a third gRNA molecule and a fourth gRNA molecule. For example, the targeting domain of a first and second gRNA molecule are configured such that two single strand breaks are positioned upstream of the target position in the HBB gene, e.g., E6V, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position in the HBB gene, e.g., E6V; and the targeting domains of a third and fourth gRNA molecule are configured such that two single strand breaks are positioned downstream of the target position in the HBB gene, e.g., E6V, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position in the HBB gene, e.g., E6V.

In an embodiment, a mutation in the HBB gene, e.g., E6V is corrected using an exogenously provided template nucleic acid, e.g., by HDR. In another embodiment, a mutation in the HBB gene, e.g., E6V is corrected without using an exogenously provided template nucleic acid, e.g., by HDR. In an embodiment, alteration of the target sequence occurs with an endogenous genomic donor sequence, e.g., by HDR. In an embodiment, the endogenous genomic donor sequence comprises one or more nucleotides derived from the HBD gene. In an embodiment, a mutation in the HBB gene, e.g., E6V is corrected by an endogenous genomic donor sequence (e.g, an HBD gene). In an embodiment, an eaCas9 molecule, e.g., an eaCas9 molecule described herein, is used. In an embodiment, the eaCas9 molecule comprises HNH-like domain cleavage activity but has no, or no significant, N-terminal RuvC-like domain cleavage activity. In an embodiment, the eaCas9 molecule is an HNH-like domain nickase. In an embodiment, the eaCas9 molecule comprises a mutation at D10 (e.g., D10A). In an embodiment, the eaCas9 molecule comprises N-terminal RuvC-like domain cleavage activity but has no, or no significant, HNH-like domain cleavage activity. In an embodiment, the eaCas9 molecule is an N-terminal RuvC-like domain nickase. In an embodiment, the eaCas9 molecule comprises a mutation at H840 (e.g., H840A) or N863 (e.g., N863A).

Methods of Altering BCL11A

One approach to increase the expression of HbF involves identification of genes whose products play a role in the regulation of globin gene expression. One such gene is BCL11A. It plays a role in the regulation of γ globin expression. It was first identified because of its role in lymphocyte development. BCL11A encodes a zinc finger protein that is thought to be involved in the stage specific regulation of γ globin expression. The BCL11A gene product is expressed in adult erythroid precursor cells and down-regulation of its expression leads to an increase in 7 globin expression. In addition, it appears that the splicing of the BCL11A mRNA is developmentally regulated. In embryonic cells, it appears that the shorter BCL11A mRNA variants, known as BCL11A-S and BCL11A-XS are primary expressed, while in adult cells, the longer BCL11A-L and BCL11A-XL mRNA variants are predominantly expressed. See, Sankaran et al (2008) Science 322 p. 1839. The BCL11A protein appears to interact with the β globin locus to alter its conformation and thus its expression at different developmental stages. Thus, if BCL11A expression is altered e.g., disrupted (e.g., reduced or eliminated), it results in the elevation of γ globin and HbF production.

Disclosed herein are methods for altering the SCD target position in the BCL11A gene. Altering the SCD target position is achieved, e.g., by:

(1) knocking out the BCL11A gene:

-   -   (a) insertion or deletion (e.g., NHEJ-mediated insertion or         deletion) of one or more nucleotides in close proximity to or         within the early coding region of the BCL11A gene, or     -   (b) deletion (e.g., NHEJ-mediated deletion) of a genomic         sequence including the erythroid enhancer of the BCL11A gene, or

(2) knocking down the BCL11A gene mediated by enzymatically inactive Cas9 (eiCas9) molecule or an eiCas9-fusion protein by targeting the promoter region of the gene.

All approaches give rise to alteration of the BCL11A gene.

In one embodiment, methods described herein introduce one or more breaks near the early coding region in at least one allele of the BCL11A gene. In another embodiment, methods described herein introduce two or more breaks to flank the erythroid enhancer of SCD target knockout position. The two or more breaks remove (e.g., delete) genomic sequence including the erythorid enhancer. In another embodiment, methods described herein comprises knocking down the BCL11A gene mediated by enzymatically inactive Cas9 (eiCas9) molecule or an eiCas9-fusion protein by targeting the promoter region of SCD target knockdown position. All methods described herein result in alteration of the BCL11A gene.

NHEJ-Mediated Introduction of an Indel in Close Proximity to or within the Early Coding Region of the SCD Knockout Position

In an embodiment, the method comprises introducing a NHEJ-mediated insertion or deletion of one more nucleotides in close proximity to the SCD target knockout position (e.g., the early coding region) of the BCL11A gene. As described herein, in one embodiment, the method comprises the introduction of one or more breaks (e.g., single strand breaks or double strand breaks) sufficiently close to (e.g., either 5′ or 3′ to) the early coding region of the SCD target knockout position, such that the break-induced indel could be reasonably expected to span the SCD target knockout position (e.g., the early coding region). While not wishing to be bound by theory, it is believed that NHEJ-mediated repair of the break(s) allows for the NHEJ-mediated introduction of an indel in close proximity to within the early coding region of the SCD target knockout position.

In an embodiment, the targeting domain of the gRNA molecule is configured to provide a cleavage event, e.g., a double strand break or a single strand break, sufficiently close to the early coding region in the BCL11A gene to allow alteration, e.g., alteration associated with NHEJ in the BCL11A gene. In an embodiment, the targeting domain is configured such that a cleavage event, e.g., a double strand or single strand break, is positioned within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of a SCD target knockout position. The break, e.g., a double strand or single strand break, can be positioned upstream or downstream of a SCD target knockout position in the BCL11A gene.

In an embodiment, a second gRNA molecule comprising a second targeting domain is configured to provide a cleavage event, e.g., a double strand break or a single strand break, sufficiently close to the early coding region in the BCL11A gene, to allow alteration, e.g., alteration associated with NHEJ in the BCL11A gene, either alone or in combination with the break positioned by said first gRNA molecule. In an embodiment, the targeting domains of the first and second gRNA molecules are configured such that a cleavage event, e.g., a double strand or single strand break, is positioned, independently for each of the gRNA molecules, within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position. In an embodiment, the breaks, e.g., double strand or single strand breaks, are positioned on both sides of a nucleotide of a SCD target knockout position in the BCL11A gene. In an embodiment, the breaks, e.g., double strand or single strand breaks, are positioned on one side, e.g., upstream or downstream, of a nucleotide of a SCD target knockout position in the BCL11A gene.

In an embodiment, a single strand break is accompanied by an additional single strand break, positioned by a second gRNA molecule, as discussed below. For example, The targeting domains bind configured such that a cleavage event, e.g., the two single strand breaks, are positioned within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the early coding region in the BCL11A gene. In an embodiment, the first and second gRNA molecules are configured such, that when guiding a Cas9 nickase, a single strand break will be accompanied by an additional single strand break, positioned by a second gRNA, sufficiently close to one another to result in alteration of the early coding region in the BCL11A gene. In an embodiment, the first and second gRNA molecules are configured such that a single strand break positioned by said second gRNA is within 10, 20, 30, 40, or 50 nucleotides of the break positioned by said first gRNA molecule, e.g., when the Cas9 is a nickase. In an embodiment, the two gRNA molecules are configured to position cuts at the same position, or within a few nucleotides of one another, on different strands, e.g., essentially mimicking a double strand break.

In an embodiment, a double strand break can be accompanied by an additional double strand break, positioned by a second gRNA molecule, as is discussed below. For example, the targeting domain of a first gRNA molecule is configured such that a double strand break is positioned upstream of the early coding region in the BCL11A gene, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position; and the targeting domain of a second gRNA molecule is configured such that a double strand break is positioned downstream of the early coding region in the BCL11A gene, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position.

In an embodiment, a double strand break can be accompanied by two additional single strand breaks, positioned by a second gRNA molecule and a third gRNA molecule. For example, the targeting domain of a first gRNA molecule is configured such that a double strand break is positioned upstream of the early coding region in the BCL11A gene, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position; and the targeting domains of a second and third gRNA molecule are configured such that two single strand breaks are positioned downstream of the early coding region in the BCL11A gene, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the target position. In an embodiment, the targeting domain of the first, second and third gRNA molecules are configured such that a cleavage event, e.g., a double strand or single strand break, is positioned, independently for each of the gRNA molecules.

In an embodiment, a first and second single strand breaks can be accompanied by two additional single strand breaks positioned by a third gRNA molecule and a fourth gRNA molecule. For example, the targeting domain of a first and second gRNA molecule are configured such that two single strand breaks are positioned upstream of the early coding region in the BCL11A gene, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the early coding region in the BCL11A gene; and the targeting domains of a third and fourth gRNA molecule are configured such that two single strand breaks are positioned downstream of a SCD target knockout position in the early coding region in the BCL11A gene, e.g., within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450 or 500 nucleotides of the early coding region in the BCL11A gene.

NHEJ-Mediated Deletion of the Erythroid Enhancer at the SCD Target Position

In an embodiment, the method comprises introducing a NHEJ-mediated deletion of a genomic sequence including the erythroid enhancer. As described herein, in one embodiment, the method comprises the introduction of two double strand breaks-one 5′ and the other 3′ to (i.e., flanking) the SCD target position (e.g., the erythroid enhancer). Two gRNAs, e.g., unimolecular (or chimeric) or modular gRNA molecules, are configured to position the two double strand breaks on opposite sides of the SCD target knockdown position (e.g., the erythroid enhancer) in the BCL11A gene. In an embodiment, the first double strand break is positioned upstream of the erythroid enhancer within intron 2 (e.g., between TSS+0.75 kb to TSS+52.0 kb), and the second double strand break is positioned downstream of the erythroid enhancer within intron 2 (e.g., between TSS+64.4 kb to TSS+84.7 kb) (see FIG. 10 ). In an embodiment, the two double strand breaks are positioned to remove a portion of the erythroid enhancer resulting in disruption of one or more DHSs. In an embodiment, the breaks (i.e., the two double strand breaks) are positioned to avoid unwanted target chromosome elements, such as repeat elements, e.g., an Alu repeat, or the endogenous splice sites.

The first double strand break may be positioned as follows:

-   -   (1) upstream of the 5′ end of the erythroid enhancer in intron 2         (e.g., between TSS+0.75 kb to TSS+52.0 kb), or     -   (2) within the erythroid enhancer provided that a portion of the         erythroid enhancer is removed resulting in disruption of one or         more DHSs (e.g., between TSS+52.0 kb to TSS+64.4 kb), and the         second double strand break to be paired with the first double         strand break may be positioned as follows:     -   (1) downstream the 3′ end of the erythroid enhancer in intron 2         (e.g., between TSS+64.4 kb to TSS+84.7 kb), or     -   (2) within the erythroid enhancer provided that a portion of the         erythroid enhancer is removed resulting in disruption of one or         more DHSs (e.g., between TSS+52.0 kb to TSS+64.4 kb).

For example, the first double strand break may be positioned in the BCL11A gene:

(1) between TSS+0.75 kb to TSS+10 kb,

(2) between TSS+10 kb to TSS+20 kb,

(3) between TSS+20 kb to TSS+30 kb,

(4) between TSS+30 kb to TSS+40 kb,

(5) between TSS+40 kb to TSS+45 kb,

(6) between TSS+45 kb to TSS+47.5 kb,

(7) between TSS+47.5 kb to TSS+50 kb,

(8) between TSS+50 kb to TSS+51 kb,

(9) between TSS+51 kb to TSS+51.1 kb,

(10) between TSS+51.1 kb to TSS+51.2 kb,

(11) between TSS+51.2 kb to TSS+51.3 kb,

(12) between TSS+51.3 kb to TSS+51.4 kb,

(13) between TSS+51.4 kb to TSS+51.5 kb,

(14) between TSS+51.5 kb to TSS+51.6 kb,

(15) between TSS+51.6 kb to TSS+51.7 kb,

(16) between TSS+51.7 kb to TSS+51.8 kb,

(17) between TSS+51.8 kb to TSS+51.9 kb,

(18) between TSS+51.9 kb to TSS+52 kb,

(19) between TSS+52 kb to TSS+53 kb,

(20) between TSS+53 kb to TSS+54 kb,

(21) between TSS+54 kb to TSS+55 kb,

(22) between TSS+55 kb to TSS+56 kb,

(23) between TSS+56 kb to TSS+57 kb,

(24) between TSS+57 kb to TSS+58 kb,

(25) between TSS+58 kb to TSS+59 kb,

(26) between TSS+59 kb to TSS+60 kb,

(27) between TSS+60 kb to TSS+61 kb,

(28) between TSS+61 kb to TSS+62 kb,

(29) between TSS+62 kb to TSS+63 kb,

(30) between TSS+63 kb to TSS+64 kb, or

(31) between TSS+64 kb to TSS+64.4 kb,

and the second double strand break to be paired with the first double strand break may be positioned in the BCL11A gene:

(1) between TSS+52 kb to TSS+53 kb,

(2) between TSS+53 kb to TSS+54 kb,

(3) between TSS+54 kb to TSS+55 kb,

(4) between TSS+55 kb to TSS+56 kb,

(5) between TSS+56 kb to TSS+57 kb,

(6) between TSS+57 kb to TSS+58 kb,

(7) between TSS+58 kb to TSS+59 kb,

(8) between TSS+59 kb to TSS+60 kb,

(9) between TSS+60 kb to TSS+61 kb,

(10) between TSS+61 kb to TSS+62 kb,

(11) between TSS+62 kb to TSS+63 kb,

(12) between TSS+63 kb to TSS+64 kb,

(13) between TSS+64 kb to TSS+64.4 kb,

(14) between TSS+64.4 kb to TSS+65 kb,

(15) between TSS+65 kb to TSS+65.1 kb,

(16) between TSS+65.1 kb to TSS+65.2 kb,

(17) between TSS+65.2 kb to TSS+65.3 kb,

(18) between TSS+65.3 kb to TSS+65.4 kb,

(19) between TSS+65.4 kb to TSS+65.5 kb,

(20) between TSS+65.5 kb to TSS+65.7 kb,

(21) between TSS+65.7 kb to TSS+65.8 kb,

(22) between TSS+65.8 kb to TSS+65.9 kb,

(23) between TSS+65.9 kb to TSS+66 kb,

(24) between TSS+66 kb to TSS+67 kb,

(25) between TSS+67 kb to TSS+68 kb,

(26) between TSS+68 kb to TSS+69 kb,

(27) between TSS+69 kb to TSS+70 kb,

(28) between TSS+70 kb to TSS+75 kb,

(29) between TSS+75 kb to TSS+80 kb, or

(30) between TSS+80 kb to TSS+84.4 kb.

While not wishing to be bound by theory, it is believed that the two double strand breaks allow for NHEJ-mediated deletion of erythroid enhancer in the BCL11A gene.

In an embodiment, the method comprises introducing a NHEJ-mediated deletion of a genomic sequence including the erythroid enhancer. As described herein, in one embodiment, the method comprises the introduction of two sets of breaks (e.g., one double strand break and a pair of single strand breaks)—one 5′ and the other 3′ to (i.e., flanking) the SCD target position (e.g., the erythroid enhancer). Two gRNAs, e.g., unimolecular (or chimeric) or modular gRNA molecules, are configured to position the two sets of breaks (either the double strand break or the pair of single strand breaks) on opposite sides of the SCD target knockdown position (e.g., the erythroid enhancer) in the BCL11A gene. In an embodiment, the first set of breaks (either the double strand break or the pair of single strand breaks) is positioned upstream of the erythroid enhancer within intron 2 (e.g., between TSS+0.75 kb to TSS+52.0 kb), and the second set of breaks (either the double strand break or the pair of single strand breaks) is positioned downstream of the erythroid enhancer within intron 2 (e.g., between TSS+64.4 kb to TSS+84.7 kb) (see FIG. 10 ). In an embodiment, the two sets of breaks (either the double strand break or the pair of single strand breaks) are positioned to remove a portion of the erythroid enhancer resulting in disruption of one or more DHSs. In an embodiment, the breaks (i.e., the two sets of breaks (either the double strand break or the pair of single strand breaks)) are positioned to avoid unwanted target chromosome elements, such as repeat elements, e.g., an Alu repeat, or the endogenous splice sites.

The first set of breaks (either the double strand break or the pair of single strand breaks) may be positioned as follows:

-   -   (1) upstream of the 5′ end of the erythroid enhancer in intron 2         (e.g., between TSS+0.75 kb to TSS+52.0 kb), or     -   (2) within the erythroid enhancer provided that a portion of the         erythroid enhancer is removed resulting in disruption of one or         more DHSs (e.g., between TSS+52.0 kb to TSS+64.4 kb),         and the second set of breaks (either the double strand break or         the pair of single strand breaks) to be paired with the first         set of breaks (either the double strand break or the pair of         single strand breaks) may be positioned as follows:     -   (1) downstream the 3′ end of the erythroid enhancer in intron 2         (e.g., between TSS+64.4 kb to TSS+84.7 kb), or     -   (2) within the erythroid enhancer provided that a portion of the         erythroid enhancer is removed resulting in disruption of one or         more DHSs (e.g., between TSS+52.0 kb to TSS+64.4 kb).

For example, the first set of breaks (either the double strand break or the pair of single strand breaks) may be positioned in the BCL11A gene:

(1) between TSS+0.75 kb to TSS+10 kb,

(2) between TSS+10 kb to TSS+20 kb,

(3) between TSS+20 kb to TSS+30 kb,

(4) between TSS+30 kb to TSS+40 kb,

(5) between TSS+40 kb to TSS+45 kb,

(6) between TSS+45 kb to TSS+47.5 kb,

(7) between TSS+47.5 kb to TSS+50 kb,

(8) between TSS+50 kb to TSS+51 kb,

(9) between TSS+51 kb to TSS+51.1 kb,

(10) between TSS+51.1 kb to TSS+51.2 kb,

(11) between TSS+51.2 kb to TSS+51.3 kb,

(12) between TSS+51.3 kb to TSS+51.4 kb,

(13) between TSS+51.4 kb to TSS+51.5 kb,

(14) between TSS+51.5 kb to TSS+51.6 kb,

(15) between TSS+51.6 kb to TSS+51.7 kb,

(16) between TSS+51.7 kb to TSS+51.8 kb,

(17) between TSS+51.8 kb to TSS+51.9 kb,

(18) between TSS+51.9 kb to TSS+52 kb,

(19) between TSS+52 kb to TSS+53 kb,

(20) between TSS+53 kb to TSS+54 kb,

(21) between TSS+54 kb to TSS+55 kb,

(22) between TSS+55 kb to TSS+56 kb,

(23) between TSS+56 kb to TSS+57 kb,

(24) between TSS+57 kb to TSS+58 kb,

(25) between TSS+58 kb to TSS+59 kb,

(26) between TSS+59 kb to TSS+60 kb,

(27) between TSS+60 kb to TSS+61 kb,

(28) between TSS+61 kb to TSS+62 kb,

(29) between TSS+62 kb to TSS+63 kb,

(30) between TSS+63 kb to TSS+64 kb, or

(31) between TSS+64 kb to TSS+64.4 kb,

and the second set of breaks (either the double strand break or the pair of single strand breaks) to be paired with the first set of breaks (either the double strand break or the pair of single strand breaks) may be positioned in the BCL11A gene:

(1) between TSS+52 kb to TSS+53 kb,

(2) between TSS+53 kb to TSS+54 kb,

(3) between TSS+54 kb to TSS+55 kb,

(4) between TSS+55 kb to TSS+56 kb,

(5) between TSS+56 kb to TSS+57 kb,

(6) between TSS+57 kb to TSS+58 kb,

(7) between TSS+58 kb to TSS+59 kb,

(8) between TSS+59 kb to TSS+60 kb,

(9) between TSS+60 kb to TSS+61 kb,

(10) between TSS+61 kb to TSS+62 kb,

(11) between TSS+62 kb to TSS+63 kb,

(12) between TSS+63 kb to TSS+64 kb,

(13) between TSS+64 kb to TSS+64.4 kb,

(14) between TSS+64.4 kb to TSS+65 kb,

(15) between TSS+65 kb to TSS+65.1 kb,

(16) between TSS+65.1 kb to TSS+65.2 kb,

(17) between TSS+65.2 kb to TSS+65.3 kb,

(18) between TSS+65.3 kb to TSS+65.4 kb,

(19) between TSS+65.4 kb to TSS+65.5 kb,

(20) between TSS+65.5 kb to TSS+65.7 kb,

(21) between TSS+65.7 kb to TSS+65.8 kb,

(22) between TSS+65.8 kb to TSS+65.9 kb,

(23) between TSS+65.9 kb to TSS+66 kb,

(24) between TSS+66 kb to TSS+67 kb,

(25) between TSS+67 kb to TSS+68 kb,

(26) between TSS+68 kb to TSS+69 kb,

(27) between TSS+69 kb to TSS+70 kb,

(28) between TSS+70 kb to TSS+75 kb,

(29) between TSS+75 kb to TSS+80 kb, or

(30) between TSS+80 kb to TSS+84.4 kb.

While not wishing to be bound by theory, it is believed that the two sets of breaks (either the double strand break or the pair of single strand breaks) allow for NHEJ-mediated deletion of erythroid enhancer in the BCL11A gene.

In an embodiment, the method comprises introducing a NHEJ-mediated deletion of a genomic sequence including the erythroid enhancer. As described herein, in one embodiment, the method comprises the introduction of two sets of breaks (e.g., two pairs of single strand breaks)-one 5′ and the other 3′ to (i.e., flanking) the SCD target position (e.g., the erythroid enhancer). Two gRNAs, e.g., unimolecular (or chimeric) or modular gRNA molecules, are configured to position the two sets of breaks on opposite sides of the SCD target knockdown position (e.g., the erythroid enhancer) in the BCL11A gene. In an embodiment, the first set of breaks (i.e., the first pair of single strand breaks) is positioned upstream of the erythroid enhancer within intron 2 (e.g., between TSS+0.75 kb to TSS+52.0 kb), and the second set of breaks (i.e., the second pair of single strand breaks) is positioned downstream of the erythroid enhancer within intron 2 (e.g., between TSS+64.4 kb to TSS+84.7 kb) (see FIG. 10 ). In an embodiment, the two sets of breaks (e.g., two pairs of single strand breaks)) are positioned to remove a portion of the erythroid enhancer resulting in disruption of one or more DHSs. In an embodiment, the breaks (i.e., the two pairs of single strand breaks) are positioned to avoid unwanted target chromosome elements, such as repeat elements, e.g., an Alu repeat, or the endogenous splice sites.

The first pair of single strand breaks may be positioned as follows:

-   -   (1) upstream of the 5′ end of the erythroid enhancer in intron 2         (e.g., between TSS+0.75 kb to TSS+52.0 kb), or     -   (2) within the erythroid enhancer provided that a portion of the         erythroid enhancer is removed resulting in disruption of one or         more DHSs (e.g., between TSS+52.0 kb to TSS+64.4 kb),         and the second pair of single strand breaks to be paired with         the first pair of single strand breaks may be positioned as         follows:     -   (1) downstream the 3′ end of the erythroid enhancer in intron 2         (e.g., between TSS+64.4 kb to TSS+84.7 kb), or     -   (2) within the erythroid enhancer provided that a portion of the         erythroid enhancer is removed resulting in disruption of one or         more DHSs (e.g., between TSS+52.0 kb to TSS+64.4 kb).

For example, the pair of single strand breaks may be positioned in the BCL11A gene:

(1) between TSS+0.75 kb to TSS+10 kb,

(2) between TSS+10 kb to TSS+20 kb,

(3) between TSS+20 kb to TSS+30 kb,

(4) between TSS+30 kb to TSS+40 kb,

(5) between TSS+40 kb to TSS+45 kb,

(6) between TSS+45 kb to TSS+47.5 kb,

(7) between TSS+47.5 kb to TSS+50 kb,

(8) between TSS+50 kb to TSS+51 kb,

(9) between TSS+51 kb to TSS+51.1 kb,

(10) between TSS+51.1 kb to TSS+51.2 kb,

(11) between TSS+51.2 kb to TSS+51.3 kb,

(12) between TSS+51.3 kb to TSS+51.4 kb,

(13) between TSS+51.4 kb to TSS+51.5 kb,

(14) between TSS+51.5 kb to TSS+51.6 kb,

(15) between TSS+51.6 kb to TSS+51.7 kb,

(16) between TSS+51.7 kb to TSS+51.8 kb,

(17) between TSS+51.8 kb to TSS+51.9 kb,

(18) between TSS+51.9 kb to TSS+52 kb,

(19) between TSS+52 kb to TSS+53 kb,

(20) between TSS+53 kb to TSS+54 kb,

(21) between TSS+54 kb to TSS+55 kb,

(22) between TSS+55 kb to TSS+56 kb,

(23) between TSS+56 kb to TSS+57 kb,

(24) between TSS+57 kb to TSS+58 kb,

(25) between TSS+58 kb to TSS+59 kb,

(26) between TSS+59 kb to TSS+60 kb,

(27) between TSS+60 kb to TSS+61 kb,

(28) between TSS+61 kb to TSS+62 kb,

(29) between TSS+62 kb to TSS+63 kb,

(30) between TSS+63 kb to TSS+64 kb, or

(31) between TSS+64 kb to TSS+64.4 kb,

and the second pair of single strand breaks to be paired with the first pair of single strand breaks may be positioned in the BCL11A gene:

(1) between TSS+52 kb to TSS+53 kb,

(2) between TSS+53 kb to TSS+54 kb,

(3) between TSS+54 kb to TSS+55 kb,

(4) between TSS+55 kb to TSS+56 kb,

(5) between TSS+56 kb to TSS+57 kb,

(6) between TSS+57 kb to TSS+58 kb,

(7) between TSS+58 kb to TSS+59 kb,

(8) between TSS+59 kb to TSS+60 kb,

(9) between TSS+60 kb to TSS+61 kb,

(10) between TSS+61 kb to TSS+62 kb,

(11) between TSS+62 kb to TSS+63 kb,

(12) between TSS+63 kb to TSS+64 kb,

(13) between TSS+64 kb to TSS+64.4 kb,

(14) between TSS+64.4 kb to TSS+65 kb,

(15) between TSS+65 kb to TSS+65.1 kb,

(16) between TSS+65.1 kb to TSS+65.2 kb,

(17) between TSS+65.2 kb to TSS+65.3 kb,

(18) between TSS+65.3 kb to TSS+65.4 kb,

(19) between TSS+65.4 kb to TSS+65.5 kb,

(20) between TSS+65.5 kb to TSS+65.7 kb,

(21) between TSS+65.7 kb to TSS+65.8 kb,

(22) between TSS+65.8 kb to TSS+65.9 kb,

(23) between TSS+65.9 kb to TSS+66 kb,

(24) between TSS+66 kb to TSS+67 kb,

(25) between TSS+67 kb to TSS+68 kb,

(26) between TSS+68 kb to TSS+69 kb,

(27) between TSS+69 kb to TSS+70 kb,

(28) between TSS+70 kb to TSS+75 kb,

(29) between TSS+75 kb to TSS+80 kb, or

(30) between TSS+80 kb to TSS+84.4 kb.

While not wishing to be bound by theory, it is believed that the two sets of breaks (e.g., the two pair of single strand breaks) allow for NHEJ-mediated deletion of erythroid enhancer in the BCL11A gene.

Knocking Down the BCL11A Gene Mediated by an Enzymatically Inactive Cas9 (eiCas9) Molecule or an eiCas9-Fusion Protein by Targeting the Promoter Region of the Gene.

A targeted knockdown approach reduces or eliminates expression of functional BCL11A gene product. As described herein, a targeted knockdown is mediated by targeting an enzymatically inactive Cas9 (eiCas9) molecule or an eiCas9 fused to a transcription repressor domain or chromatin modifying protein to alter transcription, e.g., to block, reduce, or decrease transcription, of the BCL11A gene. In an embodiment, one or more eiCas9s may be used to block binding of one or more endogenous transcription factors. In another embodiment, an eiCas9 can be fused to a chromatin modifying protein. Altering chromatin status can result in decreased expression of the target gene. One or more eiCas9s fused to one or more chromatin modifying proteins may be used to alter chromatin status.

Methods and compositions discussed herein may be used to alter the expression of the BCL11A gene to treat or prevent SCD by targeting a promoter region of the BCL11A gene. In an embodiment, the promoter region, e.g., at least 2 kb, at least 1.5 kb, at least 1.0 kb, or at least 0.5 kb upstream or downstream of the TSS is targeted to knockdown expression of the BCL11A gene. In an embodiment, the methods and compositions discussed herein may be used to knock down the BCL11A gene to treat or prevent SCD by targeting 0.5 kb upstream or downstream of the TSS. A targeted knockdown approach reduces or eliminates expression of functional BCL11A gene product. As described herein, a targeted knockdown is mediated by targeting an enzymatically inactive Cas9 (eiCas9) molecule or an eiCas9 fused to a transcription repressor domain or chromatin modifying protein to alter transcription, e.g., to block, reduce, or decrease transcription, of the BCL11A gene.

Methods to Treat or Prevent Sickle Cell Disease (SCD)

Disclosed herein are the approaches to treat or prevent SCD, using the compositions and methods described herein.

One approach to treat or prevent SCD is to repair (i.e., correct) one or more mutations in the HBB gene, e.g., by HDR. In this approach, mutant HBB allele(s) are corrected and restored to wild type state. While not wishing to be bound by theory, it is believed that correction of the glutamic acid to valine substitution at amino acid 6 in the beta-globin gene restores wild type beta-globin production within erythroid cells. The method described herein can be performed in all cell types. Beta-globin is expressed in cells of erythroid cell lineage. In an embodiment, an erythroid cell is targeted.

In an embodiment, one HBB allele is repaired in the subject. In another embodiment, both HBB alleles are repaired in the subject. In either situation, the subjects can be cured of disease. As the disease only displays a phenotype when both alleles are mutated, repair of a single allele is adequate for a cure.

In one approach, the BCL11A gene is targeted as a targeted knockout or knockdown, e.g., to increase expression of fetal hemoglobin.

While not wishing to be bound by theory, it is considered that increasing levels of fetal hemoglobin (HbF) in subjects with SCD may ameliorate disease. Fetal hemoglobin can replace beta hemoglobin in the hemoglobin complex, form adequate tetramers with alpha hemoglobin, and effectively carry oxygen to tissues. Subjects with beta-thalassemia who express higher levels of fetal hemoglobin have been found to have a less severe phenotype. Hydroxyurea, often used in the treatment of beta-thalassemia, may exert its mechanism of action via increasing levels of HbF production.

In an embodiment, knockout or knockdown of the BCL11A gene increases fetal hemoglobin levels in beta-thalassemia subjects and improves phenotype and/or reduces or prevents disease progression. BCL11A is a zinc-finger repressor that is involved in the regulation of fetal hemoglobin and acts to repress the synthesis of fetal hemoglobin. Knockout of the BCL11A gene in erythroid cells induces increased fetal hemoglobin (HbF) synthesis and increased HbF can result in more effective oxygen carrying capacity in subjects with beta-thalassemia (HbF will form tetramers with hemoglobin alpha).

In an embodiment, the BCL11A knockout or knockdown is targeted specifically to cells of the erythroid lineage. BCL11A knockout in erythroid cells has been found in in vitro studies to have no effect on erythroid growth, maturation and function. In an embodiment, erythroid cells are preferentially targeted, e.g., at least 90%, 95%, 96%, 97%, 98%, 99%, or 100% of the targeted cells are erythroid cells. For example, in the case of in vivo delivery, erythroid cells are preferentially targeted, and if cells are treated ex vivo and returned to the subject, erythroid cells are preferentially modified.

In an embodiment, the methods described herein result in increased fetal hemoglobin synthesis in beta thalassemia subjects, thereby improving disease phenotype in subjects with SCD. For example, subjects with beta thalassemia major will suffer from less severe anemia and will need fewer blood transfusions. They will therefore have fewer complications arising from transfusions and chelation therapy. In an embodiment, the method described herein increases fetal hemoglobin synthesis and improves the oxygen carrying capacity of erythroid cells. For example, subjects are expected to demonstrate decreased rates of extramedullary erythropoiesis and decreased erythroid hypertrophy within the bone marrow compared to a subject who has not received the therapy. In an embodiment, the method described herein results in reduction of bone fractures, bone abnormalities, splenomegaly, and thrombosis compared to a subject who has not received the therapy.

Knockdown or knockout of one or both BCL11A alleles may be performed prior to disease onset or after disease onset, but preferably early in the disease course.

In an embodiment, the method comprises initiating treatment of a subject prior to disease onset.

In an embodiment, the method comprises initiating treatment of a subject after disease onset.

In an embodiment, the method comprises initiating treatment of a subject well after disease onset, e.g., 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 12, 16, 24, 36, 48 or more months after onset of SCD. While not wishing to be bound by theory it is believed that this treatment may be effective if subjects present well into the course of illness.

In an embodiment, the method comprises initiating treatment of a subject in an advanced stage of disease.

Overall, initiation of treatment for subjects at all stages of disease is expected to prevent negative consequences of disease and be of benefit to subjects.

In an embodiment, the method comprises initiating treatment of a subject prior to disease expression. In an embodiment, the method comprises initiating treatment of a subject in an early stage of disease, e.g., when a subject has tested positive for beta-thalassemia mutations but has no signs or symptoms associated with beta-thalassemia major, minor or intermedia.

In an embodiment, the method comprises initiating treatment of a subject at the appearance of microcytic anemia, e.g., in an infant, child, adult or young adult.

In an embodiment, the method comprises initiating treatment of a subject who is transfusion-dependent.

In an embodiment, the method comprises initiating treatment of a subject who has tested positive for a mutation in a beta globin gene.

In an embodiment, the method comprises initiating treatment at the appearance of any one or more of the following findings associated or consistent with beta-thalassemia major or beta-thalassemia minor: anemia, diarrhea, fever, failure to thrive, frontal bossing, broken long bones, hepatomegaly, splenomegaly, thrombosis, pulmonary embolus, stroke, leg ulcer, cardiomyopathy, cardiac arrhythmia, and evidence of extramedullary erythropoiesis.

In an embodiment, a cell is treated, e.g., ex vivo. In an embodiment, an ex vivo treated cell is returned to a subject.

In an embodiment, allogenic or autologous bone marrow or erythroid cells are treated ex vivo. In an embodiment, an ex vivo treated allogenic or autologous bone marrow or erythroid cells are administered to the subject. In an embodiment, an erythroid cell, e.g., an autologous erythroid cell, is treated ex vivo and returned to the subject. In an embodiment, an autologous stem cell, is treated ex vivo and returned to the subject. In an embodiment, the modified HSCs are administered to the patient following no myeloablative pre-conditioning. In an embodiment, the modified HSCs are administered to the patient following mild myeloablative pre-conditioning such that following engraftment, some of the hematopoietic cells are devied from the modified HSCs. In other aspects, the HSCs are administered after full myeloablation such that following engraftment, 100% of the hematopoietic cells are derived from the modified HSCs.

In an embodiment, the method comprises delivery of a gRNA molecule and Cas9 molecule by intravenous injection, intramuscular injection, subcutaneous injection, or intra-bone marrow (IBM) injection.

In an embodiment, the method comprises delivery of a gRNA molecule and/or a Cas9 molecule by an AAV. In an embodiment, the method comprises delivery of a gRNA molecule and/or a Cas9 molecule by a lentivirus. In an embodiment, the method comprises delivery of a gRNA molecule and/or a Cas9 molecule by a nanoparticle. In an embodiment, the method comprises delivery of a gRNA molecule by a parvovirus, e.g., a modified parvovirus specifically designed to target bone marrow cells and/or CD4 cells. In an embodiment, two or more gRNA molecules (e.g., a second, third or fourth gRNA molecules) are delivered.

I. gRNA Molecules

A gRNA molecule, as that term is used herein, refers to a nucleic acid that promotes the specific targeting or homing of a gRNA molecule/Cas9 molecule complex to a target nucleic acid. gRNA molecules can be unimolecular (having a single RNA molecule), sometimes referred to herein as “chimeric” gRNAs, or modular (comprising more than one, and typically two, separate RNA molecules). A gRNA molecule comprises a number of domains. The gRNA molecule domains are described in more detail below.

Several exemplary gRNA structures, with domains indicated thereon, are provided in FIGS. 1A-1G. While not wishing to be bound by theory, in an embodiment, with regard to the three dimensional form, or intra- or inter-strand interactions of an active form of a gRNA, regions of high complementarity are sometimes shown as duplexes in FIGS. 1A-1G and other depictions provided herein.

In an embodiment, a unimolecular, or chimeric, gRNA comprises, preferably from 5′ to 3′:

-   -   a targeting domain (which is complementary to a target nucleic         acid in the HBB gene or BCL11A gene, e.g., a targeting domain         from any of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B,         7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C,         15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E,         22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31;     -   a first complementarity domain;     -   a linking domain;     -   a second complementarity domain (which is complementary to the         first complementarity domain);     -   a proximal domain; and     -   optionally, a tail domain.

In an embodiment, a modular gRNA comprises:

-   -   a first strand comprising, preferably from 5′ to 3′;         -   a targeting domain (which is complementary to a target             nucleic acid in the HBB gene or BCL11A gene, e.g., a             targeting domain from Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E,             5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12,             13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C,             19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D,             25A-25B, 26, or 31; and         -   a first complementarity domain; and     -   a second strand, comprising, preferably from 5′ to 3′:         -   optionally, a 5′ extension domain;         -   a second complementarity domain;         -   a proximal domain; and         -   optionally, a tail domain.

The domains are discussed briefly below.

The Targeting Domain

FIGS. 1A-1G provide examples of the placement of targeting domains.

The targeting domain comprises a nucleotide sequence that is complementary, e.g., at least 80, 85, 90, or 95% complementary, e.g., fully complementary, to the target sequence on the target nucleic acid. The targeting domain is part of an RNA molecule and will therefore comprise the base uracil (U), while any DNA encoding the gRNA molecule will comprise the base thymine (T). While not wishing to be bound by theory, in an embodiment, it is believed that the complementarity of the targeting domain with the target sequence contributes to specificity of the interaction of the gRNA molecule/Cas9 molecule complex with a target nucleic acid. It is understood that in a targeting domain and target sequence pair, the uracil bases in the targeting domain will pair with the adenine bases in the target sequence. In an embodiment, the target domain itself comprises in the 5′ to 3′ direction, an optional secondary domain, and a core domain. In an embodiment, the core domain is fully complementary with the target sequence. In an embodiment, the targeting domain is 5 to 50 nucleotides in length. The strand of the target nucleic acid with which the targeting domain is complementary is referred to herein as the complementary strand. Some or all of the nucleotides of the domain can have a modification, e.g., a modification found in Section VIII herein.

In an embodiment, the targeting domain is 16 nucleotides in length.

In an embodiment, the targeting domain is 17 nucleotides in length.

In an embodiment, the targeting domain is 18 nucleotides in length.

In an embodiment, the targeting domain is 19 nucleotides in length.

In an embodiment, the targeting domain is 20 nucleotides in length.

In an embodiment, the targeting domain is 21 nucleotides in length.

In an embodiment, the targeting domain is 22 nucleotides in length.

In an embodiment, the targeting domain is 23 nucleotides in length.

In an embodiment, the targeting domain is 24 nucleotides in length.

In an embodiment, the targeting domain is 25 nucleotides in length.

In an embodiment, the targeting domain is 26 nucleotides in length.

In an embodiment, the targeting domain comprises 16 nucleotides.

In an embodiment, the targeting domain comprises 17 nucleotides.

In an embodiment, the targeting domain comprises 18 nucleotides.

In an embodiment, the targeting domain comprises 19 nucleotides.

In an embodiment, the targeting domain comprises 20 nucleotides.

In an embodiment, the targeting domain comprises 21 nucleotides.

In an embodiment, the targeting domain comprises 22 nucleotides.

In an embodiment, the targeting domain comprises 23 nucleotides.

In an embodiment, the targeting domain comprises 24 nucleotides.

In an embodiment, the targeting domain comprises 25 nucleotides.

In an embodiment, the targeting domain comprises 26 nucleotides.

Targeting domains are discussed in more detail below.

The First Complementarity Domain

FIGS. 1A-1G provide examples of first complementarity domains.

The first complementarity domain is complementary with the second complementarity domain, and in an embodiment, has sufficient complementarity to the second complementarity domain to form a duplexed region under at least some physiological conditions. In an embodiment, the first complementarity domain is 5 to 30 nucleotides in length. In an embodiment, the first complementarity domain is 5 to 25 nucleotides in length. In an embodiment, the first complementary domain is 7 to 25 nucleotides in length. In an embodiment, the first complementary domain is 7 to 22 nucleotides in length. In an embodiment, the first complementary domain is 7 to 18 nucleotides in length. In an embodiment, the first complementary domain is 7 to 15 nucleotides in length. In an embodiment, the first complementary domain is 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, or 25 nucleotides in length.

In an embodiment, the first complementarity domain comprises 3 subdomains, which, in the 5′ to 3′ direction are: a 5′ subdomain, a central subdomain, and a 3′ subdomain. In an embodiment, the 5′ subdomain is 4 to 9, e.g., 4, 5, 6, 7, 8 or 9 nucleotides in length. In an embodiment, the central subdomain is 1, 2, or 3, e.g., 1, nucleotide in length. In an embodiment, the 3′ subdomain is 3 to 25, e.g., 4 to 22, 4 to 18, or 4 to 10, or 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, or 25 nucleotides in length.

The first complementarity domain can share homology with, or be derived from, a naturally occurring first complementarity domain. In an embodiment, it has at least 50% homology with a first complementarity domain disclosed herein, e.g., an S. pyogenes, S. aureus or S. thermophilus, first complementarity domain.

Some or all of the nucleotides of the domain can have a modification, e.g., a modification found in Section VIII herein.

First complementarity domains are discussed in more detail below.

The Linking Domain

FIGS. 1A-1G provide examples of linking domains.

A linking domain serves to link the first complementarity domain with the second complementarity domain of a unimolecular gRNA. The linking domain can link the first and second complementarity domains covalently or non-covalently. In an embodiment, the linkage is covalent. In an embodiment, the linking domain covalently couples the first and second complementarity domains, see, e.g., FIGS. 1B-1E. In an embodiment, the linking domain is, or comprises, a covalent bond interposed between the first complementarity domain and the second complementarity domain. Typically the linking domain comprises one or more, e.g., 2, 3, 4, 5, 6, 7, 8, 9, or 10 nucleotides.

In modular gRNA molecules the two molecules are associated by virtue of the hybridization of the complementarity domains see e.g., FIG. 1A.

A wide variety of linking domains are suitable for use in unimolecular gRNA molecules. Linking domains can consist of a covalent bond, or be as short as one or a few nucleotides, e.g., 1, 2, 3, 4, or 5 nucleotides in length. In an embodiment, a linking domain is 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, or 25 or more nucleotides in length. In an embodiment, a linking domain is 2 to 50, 2 to 40, 2 to 30, 2 to 20, 2 to 10, or 2 to 5 nucleotides in length. In an embodiment, a linking domain shares homology with, or is derived from, a naturally occurring sequence, e.g., the sequence of a tracrRNA that is 5′ to the second complementarity domain. In an embodiment, the linking domain has at least 50% homology with a linking domain disclosed herein.

Some or all of the nucleotides of the domain can have a modification, e.g., a modification found in Section VIII herein.

Linking domains are discussed in more detail below.

The 5′ Extension Domain

In an embodiment, a modular gRNA can comprise additional sequence, 5′ to the second complementarity domain, referred to herein as the 5′ extension domain, see, e.g., FIG. 1A. In an embodiment, the 5′ extension domain is, 2 to 10, 2 to 9, 2 to 8, 2 to 7, 2 to 6, 2 to 5, 2 to 4 nucleotides in length. In an embodiment, the 5′ extension domain is 2, 3, 4, 5, 6, 7, 8, 9, or 10 or more nucleotides in length.

The Second Complementarity Domain

FIGS. 1A-1G provides examples of second complementarity domains.

The second complementarity domain is complementary with the first complementarity domain, and in an embodiment, has sufficient complementarity to the second complementarity domain to form a duplexed region under at least some physiological conditions. In an embodiment, e.g., as shown in FIGS. 1A-1B, the second complementarity domain can include sequence that lacks complementarity with the first complementarity domain, e.g., sequence that loops out from the duplexed region.

In an embodiment, the second complementarity domain is 5 to 27 nucleotides in length. In an embodiment, it is longer than the first complementarity region. In an embodiment the second complementary domain is 7 to 27 nucleotides in length. In an embodiment, the second complementary domain is 7 to 25 nucleotides in length. In an embodiment, the second complementary domain is 7 to 20 nucleotides in length. In an embodiment, the second complementary domain is 7 to 17 nucleotides in length. In an embodiment, the complementary domain is 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, the second complementarity domain comprises 3 subdomains, which, in the 5′ to 3′ direction are: a 5′ subdomain, a central subdomain, and a 3′ subdomain. In an embodiment, the 5′ subdomain is 3 to 25, e.g., 4 to 22, 4 to 18, or 4 to 10, or 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, or 25 nucleotides in length. In an embodiment, the central subdomain is 1, 2, 3, 4 or 5, e.g., 3, nucleotides in length. In an embodiment, the 3′ subdomain is 4 to 9, e.g., 4, 5, 6, 7, 8 or 9 nucleotides in length.

In an embodiment, the 5′ subdomain and the 3′ subdomain of the first complementarity domain, are respectively, complementary, e.g., fully complementary, with the 3′ subdomain and the 5′ subdomain of the second complementarity domain.

The second complementarity domain can share homology with or be derived from a naturally occurring second complementarity domain. In an embodiment, it has at least 50% homology with a second complementarity domain disclosed herein, e.g., an S. pyogenes, S. aureus or S. thermophilus, first complementarity domain.

Some or all of the nucleotides of the domain can have a modification, e.g., a modification found in Section VIII herein.

A Proximal domain

FIGS. 1A-1G provide examples of proximal domains.

In an embodiment, the proximal domain is 5 to 20 nucleotides in length. In an embodiment, the proximal domain can share homology with or be derived from a naturally occurring proximal domain. In an embodiment, it has at least 50% homology with a proximal domain disclosed herein, e.g., an S. pyogenes, S. aureus or S. thermophilus, proximal domain.

Some or all of the nucleotides of the domain can have a modification, e.g., modification found in Section VIII herein.

A Tail Domain

FIGS. 1A-1G provide examples of tail domains.

As can be seen by inspection of the tail domains in FIGS. 1A-1E, a broad spectrum of tail domains are suitable for use in gRNA molecules. In an embodiment, the tail domain is 0 (absent), 1, 2, 3, 4, 5, 6, 7, 8, 9, or 10 nucleotides in length. In embodiment, the tail domain nucleotides are from or share homology with sequence from the 5′ end of a naturally occurring tail domain, see e.g., panels 4a or 5a of FIG. 1D or FIG. 1E. In an embodiment, the tail domain includes sequences that are complementary to each other and which, under at least some physiological conditions, form a duplexed region.

In an embodiment, the tail domain is absent or is 1 to 50 nucleotides in length. In an embodiment, the tail domain can share homology with or be derived from a naturally occurring proximal tail domain. In an embodiment, it has at least 50% homology with a tail domain disclosed herein, e.g., an S. pyogenes, S. aureus or S. thermophilus, tail domain.

In an embodiment, the tail domain includes nucleotides at the 3′ end that are related to the method of in vitro or in vivo transcription. When a T7 promoter is used for in vitro transcription of the gRNA, these nucleotides may be any nucleotides present before the 3′ end of the DNA template. When a U6 promoter is used for in vivo transcription, these nucleotides may be the sequence UUUUUU. When alternate pol-III promoters are used, these nucleotides may be various numbers or uracil bases or may include alternate bases.

The domains of gRNA molecules are described in more detail below.

The Targeting Domain

The “targeting domain” of the gRNA is complementary to the “target domain” on the target nucleic acid. The strand of the target nucleic acid comprising the nucleotide sequence complementary to the core domain of the gRNA is referred to herein as the “complementary strand” of the target nucleic acid. Guidance on the selection of targeting domains can be found, e.g., in Fu Y et al., Nat Biotechnol 2014 (doi: 10.1038/nbt.2808) and Sternberg S H et al., Nature 2014 (doi: 10.1038/nature13011).

In an embodiment, the targeting domain is 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, the targeting domain is 16 nucleotides in length.

In an embodiment, the targeting domain is 17 nucleotides in length.

In an embodiment, the targeting domain is 18 nucleotides in length.

In an embodiment, the targeting domain is 19 nucleotides in length.

In an embodiment, the targeting domain is 20 nucleotides in length.

In an embodiment, the targeting domain is 21 nucleotides in length.

In an embodiment, the targeting domain is 22 nucleotides in length.

In an embodiment, the targeting domain is 23 nucleotides in length.

In an embodiment, the targeting domain is 24 nucleotides in length.

In an embodiment, the targeting domain is 25 nucleotides in length.

In an embodiment, the targeting domain is 26 nucleotides in length.

In an embodiment, the targeting domain comprises 16 nucleotides.

In an embodiment, the targeting domain comprises 17 nucleotides.

In an embodiment, the targeting domain comprises 18 nucleotides.

In an embodiment, the targeting domain comprises 19 nucleotides.

In an embodiment, the targeting domain comprises 20 nucleotides.

In an embodiment, the targeting domain comprises 21 nucleotides.

In an embodiment, the targeting domain comprises 22 nucleotides.

In an embodiment, the targeting domain comprises 23 nucleotides.

In an embodiment, the targeting domain comprises 24 nucleotides.

In an embodiment, the targeting domain comprises 25 nucleotides.

In an embodiment, the targeting domain comprises 26 nucleotides.

In an embodiment, the targeting domain is 10+/−5, 20+/−5, 30+/−5, 40+/−5, 50+/−5, 60+/−5, 70+/−5, 80+/−5, 90+/−5, or 100+/−5 nucleotides, in length.

In an embodiment, the targeting domain is 20+/−5 nucleotides in length.

In an embodiment, the targeting domain is 20+/−10, 30+/−10, 40+/−10, 50+/−10, 60+/−10, 70+/−10, 80+/−10, 90+/−10, or 100+/−10 nucleotides, in length.

In an embodiment, the targeting domain is 30+/−10 nucleotides in length.

In an embodiment, the targeting domain is 10 to 100, 10 to 90, 10 to 80, 10 to 70, 10 to 60, 10 to 50, 10 to 40, 10 to 30, 10 to 20 or 10 to 15 nucleotides in length.

In another embodiment, the targeting domain is 20 to 100, 20 to 90, 20 to 80, 20 to 70, 20 to 60, 20 to 50, 20 to 40, 20 to 30, or 20 to 25 nucleotides in length.

Typically the targeting domain has full complementarity with the target sequence. In an embodiment the targeting domain has or includes 1, 2, 3, 4, 5, 6, 7 or 8 nucleotides that are not complementary with the corresponding nucleotide of the targeting domain.

In an embodiment, the target domain includes 1, 2, 3, 4 or 5 nucleotides that are complementary with the corresponding nucleotide of the targeting domain within 5 nucleotides of its 5′ end. In an embodiment, the target domain includes 1, 2, 3, 4 or 5 nucleotides that are complementary with the corresponding nucleotide of the targeting domain within 5 nucleotides of its 3′ end.

In an embodiment, the target domain includes 1, 2, 3, or 4 nucleotides that are not complementary with the corresponding nucleotide of the targeting domain within 5 nucleotides of its 5′ end. In an embodiment, the target domain includes 1, 2, 3, or 4 nucleotides that are not complementary with the corresponding nucleotide of the targeting domain within 5 nucleotides of its 3′ end.

In an embodiment, the degree of complementarity, together with other properties of the gRNA, is sufficient to allow targeting of a Cas9 molecule to the target nucleic acid.

In an embodiment, the targeting domain comprises two consecutive nucleotides that are not complementary to the target domain (“non-complementary nucleotides”), e.g., two consecutive noncomplementary nucleotides that are within 5 nucleotides of the 5′ end of the targeting domain, within 5 nucleotides of the 3′ end of the targeting domain, or more than 5 nucleotides away from one or both ends of the targeting domain.

In an embodiment, no two consecutive nucleotides within 5 nucleotides of the 5′ end of the targeting domain, within 5 nucleotides of the 3′ end of the targeting domain, or within a region that is more than 5 nucleotides away from one or both ends of the targeting domain, are not complementary to the targeting domain.

In an embodiment, there are no noncomplementary nucleotides within 5 nucleotides of the 5′ end of the targeting domain, within 5 nucleotides of the 3′ end of the targeting domain, or within a region that is more than 5 nucleotides away from one or both ends of the targeting domain.

In an embodiment, the targeting domain nucleotides do not comprise modifications, e.g., modifications of the type provided in Section VIII. However, in an embodiment, the targeting domain comprises one or more modifications, e.g., modifications that it render it less susceptible to degradation or more bio-compatible, e.g., less immunogenic. By way of example, the backbone of the targeting domain can be modified with a phosphorothioate, or other modification from Section VIII. In an embodiment, a nucleotide of the targeting domain can comprise a 2′ modification (e.g., a modification at the 2′ position on ribose), e.g., a 2-acetylation, e.g., a 2′ methylation, or other modification(s) from Section VIII.

In an embodiment, the targeting domain includes 1, 2, 3, 4, 5, 6, 7 or 8 or more modifications. In an embodiment, the targeting domain includes 1, 2, 3, or 4 modifications within 5 nucleotides of its 5′ end. In an embodiment, the targeting domain comprises as many as 1, 2, 3, or 4 modifications within 5 nucleotides of its 3′ end.

In an embodiment, the targeting domain comprises modifications at two consecutive nucleotides, e.g., two consecutive nucleotides that are within 5 nucleotides of the 5′ end of the targeting domain, within 5 nucleotides of the 3′ end of the targeting domain, or more than 5 nucleotides away from one or both ends of the targeting domain.

In an embodiment, no two consecutive nucleotides are modified within 5 nucleotides of the 5′ end of the targeting domain, within 5 nucleotides of the 3′ end of the targeting domain, or within a region that is more than 5 nucleotides away from one or both ends of the targeting domain. In an embodiment, no nucleotide is modified within 5 nucleotides of the 5′ end of the targeting domain, within 5 nucleotides of the 3′ end of the targeting domain, or within a region that is more than 5 nucleotides away from one or both ends of the targeting domain.

Modifications in the targeting domain can be selected to not interfere with targeting efficacy, which can be evaluated by testing a candidate modification in the system described in Section IV. gRNAs having a candidate targeting domain having a selected length, sequence, degree of complementarity, or degree of modification, can be evaluated in a system in Section IV. The candidate targeting domain can be placed, either alone, or with one or more other candidate changes in a gRNA molecule/Cas9 molecule system known to be functional with a selected target and evaluated.

In an embodiment, all of the modified nucleotides are complementary to and capable of hybridizing to corresponding nucleotides present in the target domain. In another embodiment, 1, 2, 3, 4, 5, 6, 7 or 8 or more modified nucleotides are not complementary to or capable of hybridizing to corresponding nucleotides present in the target domain.

In an embodiment, the targeting domain comprises, preferably in the 5′→3′ direction: a secondary domain and a core domain. These domains are discussed in more detail below.

The Core Domain and Secondary Domain of the Targeting Domain

The “core domain” of the targeting domain is complementary to the “core domain target” on the target nucleic acid. In an embodiment, the core domain comprises about 8 to about 13 nucleotides from the 3′ end of the targeting domain (e.g., the most 3′ 8 to 13 nucleotides of the targeting domain).

In an embodiment, the core domain and targeting domain, are independently, 6+/−2, 7+/−2, 8+/−2, 9+/−2, 10+/−2, 11+/−2, 12+/−2, 13+/−2, 14+/−2, 15+/−2, or 16+−2, nucleotides in length.

In an embodiment, the core domain and targeting domain, are independently, 10+/−2 nucleotides in length.

In an embodiment, the core domain and targeting domain, are independently, 10+/−4 nucleotides in length.

In an embodiment, the core domain and targeting domain are independently 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, or 18 nucleotides in length.

In an embodiment, the core domain and targeting domain are independently 3 to 20, 4 to 20, 5 to 20, 6 to 20, 7 to 20, 8 to 20, 9 to 20 10 to 20 or 15 to 20 nucleotides in length.

In an embodiment, the core domain and targeting domain are independently 3 to 15, e.g., 6 to 15, 7 to 14, 7 to 13, 6 to 12, 7 to 12, 7 to 11, 7 to 10, 8 to 14, 8 to 13, 8 to 12, 8 to 11, 8 to 10 or 8 to 9 nucleotides in length.

The core domain is complementary with the core domain target. Typically the core domain has exact complementarity with the core domain target. In an embodiment, the core domain can have 1, 2, 3, 4 or 5 nucleotides that are not complementary with the corresponding nucleotide of the core domain. In an embodiment, the degree of complementarity, together with other properties of the gRNA, is sufficient to allow targeting of a Cas9 molecule to the target nucleic acid.

The “secondary domain” of the targeting domain of the gRNA is complementary to the “secondary domain target” of the target nucleic acid.

In an embodiment, the secondary domain is positioned 5′ to the core domain.

In an embodiment, the secondary domain is absent or optional.

In an embodiment, if the targeting domain is 26 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 12 to 17 nucleotides in length.

In an embodiment, if the targeting domain is 25 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 12 to 17 nucleotides in length.

In an embodiment, if the targeting domain is 24 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 11 to 16 nucleotides in length.

In an embodiment, if the targeting domain is 23 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 10 to 15 nucleotides in length.

In an embodiment, if the targeting domain is 22 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 9 to 14 nucleotides in length.

In an embodiment, if the targeting domain is 21 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 8 to 13 nucleotides in length.

In an embodiment, if the targeting domain is 20 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 7 to 12 nucleotides in length.

In an embodiment, if the targeting domain is 19 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 6 to 11 nucleotides in length.

In an embodiment, if the targeting domain is 18 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 5 to 10 nucleotides in length.

In an embodiment, if the targeting domain is 17 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 4 to 9 nucleotides in length.

In an embodiment, if the targeting domain is 16 nucleotides in length and the core domain (counted from the 3′ end of the targeting domain) is 8 to 13 nucleotides in length, the secondary domain is 3 to 8 nucleotides in length.

In an embodiment, the secondary domain is 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14 or 15 nucleotides in length.

The secondary domain is complementary with the secondary domain target. Typically the secondary domain has exact complementarity with the secondary domain target. In an embodiment the secondary domain can have 1, 2, 3, 4 or 5 nucleotides that are not complementary with the corresponding nucleotide of the secondary domain. In an embodiment, the degree of complementarity, together with other properties of the gRNA, is sufficient to allow targeting of a Cas9 molecule to the target nucleic acid.

In an embodiment, the core domain nucleotides do not comprise modifications, e.g., modifications of the type provided in Section VIII. However, in an embodiment, the core domain comprises one or more modifications, e.g., modifications that it render it less susceptible to degradation or more bio-compatible, e.g., less immunogenic. By way of example, the backbone of the core domain can be modified with a phosphorothioate, or other modification(s) from Section VIII. In an embodiment a nucleotide of the core domain can comprise a 2′ modification (e.g., a modification at the 2′ position on ribose), e.g., a 2-acetylation, e.g., a 2′ methylation, or other modification(s) from Section VIII. Typically, a core domain will contain no more than 1, 2, or 3 modifications.

Modifications in the core domain can be selected to not interfere with targeting efficacy, which can be evaluated by testing a candidate modification in the system described in Section IV. gRNAs having a candidate core domain having a selected length, sequence, degree of complementarity, or degree of modification, can be evaluated in the system described at Section IV. The candidate core domain can be placed, either alone, or with one or more other candidate changes in a gRNA molecule/Cas9 molecule system known to be functional with a selected target and evaluated.

In an embodiment, the secondary domain nucleotides do not comprise modifications, e.g., modifications of the type provided in Section VIII. However, in an embodiment, the secondary domain comprises one or more modifications, e.g., modifications that render it less susceptible to degradation or more bio-compatible, e.g., less immunogenic. By way of example, the backbone of the secondary domain can be modified with a phosphorothioate, or other modification(s) from Section VIII. In an embodiment a nucleotide of the secondary domain can comprise a 2′ modification (e.g., a modification at the 2′ position on ribose), e.g., a 2-acetylation, e.g., a 2′ methylation, or other modification from Section VIII. Typically, a secondary domain will contain no more than 1, 2, or 3 modifications.

Modifications in the secondary domain can be selected to not interfere with targeting efficacy, which can be evaluated by testing a candidate modification in the system described in Section IV. gRNAs having a candidate secondary domain having a selected length, sequence, degree of complementarity, or degree of modification, can be evaluated in the system described at Section IV. The candidate secondary domain can be placed, either alone, or with one or more other candidate changes in a gRNA molecule/Cas9 molecule system known to be functional with a selected target and evaluated.

In an embodiment, (1) the degree of complementarity between the core domain and its target, and (2) the degree of complementarity between the secondary domain and its target, may differ. In an embodiment, (1) may be greater than (2). In an embodiment, (1) may be less than (2). In an embodiment, (1) and (2) are the same, e.g., each may be completely complementary with its target.

In an embodiment, (1) the number of modifications (e.g., modifications from Section VIII) of the nucleotides of the core domain and (2) the number of modification (e.g., modifications from Section VIII) of the nucleotides of the secondary domain, may differ. In an embodiment, (1) may be less than (2). In an embodiment, (1) may be greater than (2). In an embodiment, (1) and (2) may be the same, e.g., each may be free of modifications.

The First and Second Complementarity Domains

The first complementarity domain is complementary with the second complementarity domain.

Typically the first domain does not have exact complementarity with the second complementarity domain target. In an embodiment, the first complementarity domain can have 1, 2, 3, 4 or 5 nucleotides that are not complementary with the corresponding nucleotide of the second complementarity domain. In an embodiment, 1, 2, 3, 4, 5 or 6, e.g., 3 nucleotides, will not pair in the duplex, and, e.g., form a non-duplexed or looped-out region. In an embodiment, an unpaired, or loop-out, region, e.g., a loop-out of 3 nucleotides, is present on the second complementarity domain. In an embodiment, the unpaired region begins 1, 2, 3, 4, 5, or 6, e.g., 4, nucleotides from the 5′ end of the second complementarity domain.

In an embodiment, the degree of complementarity, together with other properties of the gRNA, is sufficient to allow targeting of a Cas9 molecule to the target nucleic acid.

In an embodiment, the first and second complementarity domains are:

independently, 6+/−2, 7+/−2, 8+/−2, 9+/−2, 10+/−2, 11+/−2, 12+/−2, 13+/−2, 14+/−2, 15+/−2, 16+/−2, 17+/−2, 18+/−2, 19+/−2, or 20+/−2, 21+/−2, 22+/−2, 23+/−2, or 24+/−2 nucleotides in length;

independently, 6, 7, 8, 9, 10, 11, 12, 13, 14, 14, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, or 26, nucleotides in length; or

independently, 5 to 24, 5 to 23, 5 to 22, 5 to 21, 5 to 20, 7 to 18, 9 to 16, or 10 to 14 nucleotides in length.

In an embodiment, the second complementarity domain is longer than the first complementarity domain, e.g., 2, 3, 4, 5, or 6, e.g., 6, nucleotides longer.

In an embodiment, the first and second complementary domains, independently, do not comprise modifications, e.g., modifications of the type provided in Section VIII.

In an embodiment, the first and second complementary domains, independently, comprise one or more modifications, e.g., modifications that the render the domain less susceptible to degradation or more bio-compatible, e.g., less immunogenic. By way of example, the backbone of the domain can be modified with a phosphorothioate, or other modification(s) from Section VIII. In an embodiment a nucleotide of the domain can comprise a 2′ modification (e.g., a modification at the 2′ position on ribose), e.g., a 2-acetylation, e.g., a 2′ methylation, or other modification(s) from Section VIII.

In an embodiment, the first and second complementary domains, independently, include 1, 2, 3, 4, 5, 6, 7 or 8 or more modifications. In an embodiment, the first and second complementary domains, independently, include 1, 2, 3, or 4 modifications within 5 nucleotides of its 5′ end. In an embodiment, the first and second complementary domains, independently, include as many as 1, 2, 3, or 4 modifications within 5 nucleotides of its 3′ end.

In an embodiment, the first and second complementary domains, independently, include modifications at two consecutive nucleotides, e.g., two consecutive nucleotides that are within 5 nucleotides of the 5′ end of the domain, within 5 nucleotides of the 3′ end of the domain, or more than 5 nucleotides away from one or both ends of the domain. In an embodiment, the first and second complementary domains, independently, include no two consecutive nucleotides that are modified, within 5 nucleotides of the 5′ end of the domain, within 5 nucleotides of the 3′ end of the domain, or within a region that is more than 5 nucleotides away from one or both ends of the domain. In an embodiment, the first and second complementary domains, independently, include no nucleotide that is modified within 5 nucleotides of the 5′ end of the domain, within 5 nucleotides of the 3′ end of the domain, or within a region that is more than 5 nucleotides away from one or both ends of the domain.

Modifications in a complementarity domain can be selected to not interfere with targeting efficacy, which can be evaluated by testing a candidate modification in the system described in Section IV. gRNAs having a candidate complementarity domain having a selected length, sequence, degree of complementarity, or degree of modification, can be evaluated in the system described in Section IV. The candidate complementarity domain can be placed, either alone, or with one or more other candidate changes in a gRNA molecule/Cas9 molecule system known to be functional with a selected target and evaluated.

In an embodiment, the first complementarity domain has at least 60, 70, 80, 85%, 90% or 95% homology with, or differs by no more than 1, 2, 3, 4, 5, or 6 nucleotides from, a reference first complementarity domain, e.g., a naturally occurring, e.g., an S. pyogenes, S. aureus or S. thermophilus, first complementarity domain, or a first complementarity domain described herein, e.g., from FIGS. 1A-1G.

In an embodiment, the second complementarity domain has at least 60, 70, 80, 85%, 90%, or 95% homology with, or differs by no more than 1, 2, 3, 4, 5, or 6 nucleotides from, a reference second complementarity domain, e.g., a naturally occurring, e.g., an S. pyogenes, S. aureus or S. thermophilus, second complementarity domain, or a second complementarity domain described herein, e.g., from FIGS. 1A-1G.

The duplexed region formed by first and second complementarity domains is typically 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 or 22 base pairs in length (excluding any looped out or unpaired nucleotides).

In an embodiment, the first and second complementarity domains, when duplexed, comprise 11 paired nucleotides, for example, in the gRNA sequence (one paired strand underlined, one bolded):

(SEQ ID NO: 5) NNNNNNNNNNNNNNNNNNNNGUUUUAGAGCUAGAAAUAGCAAGUUAAAA UAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCACCGAGUCGGUGC.

In an embodiment, the first and second complementarity domains, when duplexed, comprise 15 paired nucleotides, for example in the gRNA sequence (one paired strand underlined, one bolded):

(SEQ ID NO: 27) NNNNNNNNNNNNNNNNNNNNGUUUUAGAGCUAUGCUGAAAAGCAUAGCA AGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCACCGAGU CGGUGC.

In an embodiment the first and second complementarity domains, when duplexed, comprise 16 paired nucleotides, for example in the gRNA sequence (one paired strand underlined, one bolded):

(SEQ ID NO: 28) NNNNNNNNNNNNNNNNNNNNGUUUUAGAGCUAUGCUGGAAACAGCAUAG CAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCACCGA GUCGGUGC.

In an embodiment the first and second complementarity domains, when duplexed, comprise 21 paired nucleotides, for example in the gRNA sequence (one paired strand underlined, one bolded):

(SEQ ID NO: 29) NNNNNNNNNNNNNNNNNNNNGUUUUAGAGCUAUGCUGUUUUGGAAACAA AACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAA GUGGCACCGAGUCGGUGC.

In an embodiment, nucleotides are exchanged to remove poly-U tracts, for example in the gRNA sequences (exchanged nucleotides underlined):

(SEQ ID NO: 30) NNNNNNNNNNNNNNNNNNNNGUAUUAGAGCUAGAAAUAGCAAGUUAAUA UAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCACCGAGUCGGUGC; (SEQ ID NO: 31) NNNNNNNNNNNNNNNNNNNNGUUUAAGAGCUAGAAAUAGCAAGUUUAAA UAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCACCGAGUCGGUGC; or (SEQ ID NO: 32) NNNNNNNNNNNNNNNNNNNNGUAUUAGAGCUAUGCUGUAUUGGAAACAA UACAGCAUAGCAAGUUAAUAUAAGGCUAGUCCGUUAUCAACUUGAAAAA GUGGCACCGAGUCGGUGC.

The 5′ Extension Domain

In an embodiment, a modular gRNA can comprise additional sequence, 5′ to the second complementarity domain. In an embodiment, the 5′ extension domain is 2 to 10, 2 to 9, 2 to 8, 2 to 7, 2 to 6, 2 to 5, or 2 to 4 nucleotides in length. In an embodiment, the 5′ extension domain is 2, 3, 4, 5, 6, 7, 8, 9, or 10 or more nucleotides in length.

In an embodiment, the 5′ extension domain nucleotides do not comprise modifications, e.g., modifications of the type provided in Section VIII. However, in an embodiment, the 5′ extension domain comprises one or more modifications, e.g., modifications that it render it less susceptible to degradation or more bio-compatible, e.g., less immunogenic. By way of example, the backbone of the 5′ extension domain can be modified with a phosphorothioate, or other modification(s) from Section VIII. In an embodiment, a nucleotide of the 5′ extension domain can comprise a 2′ modification (e.g., a modification at the 2′ position on ribose), e.g., a 2-acetylation, e.g., a 2′ methylation, or other modification(s) from Section VIII.

In an embodiment, the 5′ extension domain can comprise as many as 1, 2, 3, 4, 5, 6, 7 or 8 modifications. In an embodiment, the 5′ extension domain comprises as many as 1, 2, 3, or 4 modifications within 5 nucleotides of its 5′ end, e.g., in a modular gRNA molecule. In an embodiment, the 5′ extension domain comprises as many as 1, 2, 3, or 4 modifications within 5 nucleotides of its 3′ end, e.g., in a modular gRNA molecule.

In an embodiment, the 5′ extension domain comprises modifications at two consecutive nucleotides, e.g., two consecutive nucleotides that are within 5 nucleotides of the 5′ end of the 5′ extension domain, within 5 nucleotides of the 3′ end of the 5′ extension domain, or more than 5 nucleotides away from one or both ends of the 5′ extension domain. In an embodiment, no two consecutive nucleotides are modified within 5 nucleotides of the 5′ end of the 5′ extension domain, within 5 nucleotides of the 3′ end of the 5′ extension domain, or within a region that is more than 5 nucleotides away from one or both ends of the 5′ extension domain. In an embodiment, no nucleotide is modified within 5 nucleotides of the 5′ end of the 5′ extension domain, within 5 nucleotides of the 3′ end of the 5′ extension domain, or within a region that is more than 5 nucleotides away from one or both ends of the 5′ extension domain.

Modifications in the 5′ extension domain can be selected so as to not interfere with gRNA molecule efficacy, which can be evaluated by testing a candidate modification in the system described in Section IV. gRNAs having a candidate 5′ extension domain having a selected length, sequence, degree of complementarity, or degree of modification, can be evaluated in the system described at Section IV. The candidate 5′ extension domain can be placed, either alone, or with one or more other candidate changes in a gRNA molecule/Cas9 molecule system known to be functional with a selected target and evaluated.

In an embodiment, the 5′ extension domain has at least 60, 70, 80, 85, 90 or 95% homology with, or differs by no more than 1, 2, 3, 4, 5, or 6 nucleotides from, a reference 5′ extension domain, e.g., a naturally occurring, e.g., an S. pyogenes, S. aureus or S. thermophilus, 5′ extension domain, or a 5′ extension domain described herein, e.g., from FIGS. 1A-1G.

The Linking Domain

In a unimolecular gRNA molecule the linking domain is disposed between the first and second complementarity domains. In a modular gRNA molecule, the two molecules are associated with one another by the complementarity domains.

In an embodiment, the linking domain is 10+/−5, 20+/−5, 30+/−5, 40+/−5, 50+/−5, 60+/−5, 70+/−5, 80+/−5, 90+/−5, or 100+/−5 nucleotides, in length.

In an embodiment, the linking domain is 20+/−10, 30+/−10, 40+/−10, 50+/−10, 60+/−10, 70+/−10, 80+/−10, 90+/−10, or 100+/−10 nucleotides, in length.

In an embodiment, the linking domain is 10 to 100, 10 to 90, 10 to 80, 10 to 70, 10 to 60, 10 to 50, 10 to 40, 10 to 30, 10 to 20 or 10 to 15 nucleotides in length.

In another embodiment, the linking domain is 20 to 100, 20 to 90, 20 to 80, 20 to 70, 20 to 60, 20 to 50, 20 to 40, 20 to 30, or 20 to 25 nucleotides in length.

In an embodiment, the linking domain is 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16 17, 18, 19, or 20 nucleotides in length.

In and embodiment, the linking domain is a covalent bond.

In an embodiment, the linking domain comprises a duplexed region, typically adjacent to or within 1, 2, or 3 nucleotides of the 3′ end of the first complementarity domain and/or the 5-end of the second complementarity domain. In an embodiment, the duplexed region can be 20+/−10 base pairs in length. In an embodiment, the duplexed region can be 10+/−5, 15+/−5, 20+/−5, or 30+/−5 base pairs in length. In an embodiment, the duplexed region can be 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, or 15 base pairs in length.

Typically the sequences forming the duplexed region have exact complementarity with one another, though in an embodiment as many as 1, 2, 3, 4, 5, 6, 7 or 8 nucleotides are not complementary with the corresponding nucleotides.

In an embodiment, the linking domain nucleotides do not comprise modifications, e.g., modifications of the type provided in Section VIII. However, in an embodiment, the linking domain comprises one or more modifications, e.g., modifications that it render it less susceptible to degradation or more bio-compatible, e.g., less immunogenic. By way of example, the backbone of the linking domain can be modified with a phosphorothioate, or other modification(s) from Section VIII. In an embodiment a nucleotide of the linking domain can comprise a 2′ modification (e.g., a modification at the 2′ position on ribose), e.g., a 2-acetylation, e.g., a 2′ methylation, or other modification(s) from Section VIII. In an embodiment, the linking domain can comprise as many as 1, 2, 3, 4, 5, 6, 7 or 8 modifications.

Modifications in a linking domain can be selected so as to not interfere with targeting efficacy, which can be evaluated by testing a candidate modification in the system described in Section IV. gRNAs having a candidate linking domain having a selected length, sequence, degree of complementarity, or degree of modification, can be evaluated a system described in Section IV. A candidate linking domain can be placed, either alone, or with one or more other candidate changes in a gRNA molecule/Cas9 molecule system known to be functional with a selected target and evaluated.

In an embodiment, the linking domain has at least 60, 70, 80, 85, 90 or 95% homology 30 with, or differs by no more than 1, 2, 3, 4, 5, or 6 nucleotides from, a reference linking domain, e.g., a linking domain described herein, e.g., from FIGS. 1A-1G.

The Proximal Domain

In an embodiment, the proximal domain is 6+/−2, 7+/−2, 8+/−2, 9+/−2, 10+/−2, 11+/−2, 12+/−2, 13+/−2, 14+/−2, 14+/−2, 16+/−2, 17+/−2, 18+/−2, 19+/−2, or 20+/−2 nucleotides in length.

In an embodiment, the proximal domain is 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length.

In an embodiment, the proximal domain is 5 to 20, 7, to 18, 9 to 16, or 10 to 14 nucleotides in length.

In an embodiment, the proximal domain nucleotides do not comprise modifications, e.g., modifications of the type provided in Section VIII. However, in an embodiment, the proximal domain comprises one or more modifications, e.g., modifications that it render it less susceptible to degradation or more bio-compatible, e.g., less immunogenic. By way of example, the backbone of the proximal domain can be modified with a phosphorothioate, or other modification(s) from Section VIII. In an embodiment a nucleotide of the proximal domain can comprise a 2′ modification (e.g., a modification at the 2′ position on ribose), e.g., a 2-acetylation, e.g., a 2′ methylation, or other modification(s) from Section VIII.

In an embodiment, the proximal domain can comprise as many as 1, 2, 3, 4, 5, 6, 7 or 8 modifications. In an embodiment, the proximal domain comprises as many as 1, 2, 3, or 4 modifications within 5 nucleotides of its 5′ end, e.g., in a modular gRNA molecule. In an embodiment, the target domain comprises as many as 1, 2, 3, or 4 modifications within 5 nucleotides of its 3′ end, e.g., in a modular gRNA molecule.

In an embodiment, the proximal domain comprises modifications at two consecutive nucleotides, e.g., two consecutive nucleotides that are within 5 nucleotides of the 5′ end of the proximal domain, within 5 nucleotides of the 3′ end of the proximal domain, or more than 5 nucleotides away from one or both ends of the proximal domain. In an embodiment, no two consecutive nucleotides are modified within 5 nucleotides of the 5′ end of the proximal domain, within 5 nucleotides of the 3′ end of the proximal domain, or within a region that is more than 5 nucleotides away from one or both ends of the proximal domain. In an embodiment, no nucleotide is modified within 5 nucleotides of the 5′ end of the proximal domain, within 5 nucleotides of the 3′ end of the proximal domain, or within a region that is more than 5 nucleotides away from one or both ends of the proximal domain.

Modifications in the proximal domain can be selected so as to not interfere with gRNA molecule efficacy, which can be evaluated by testing a candidate modification in the system described in Section IV. gRNAs having a candidate proximal domain having a selected length, sequence, degree of complementarity, or degree of modification, can be evaluated in the system described at Section IV. The candidate proximal domain can be placed, either alone, or with one or more other candidate changes in a gRNA molecule/Cas9 molecule system known to be functional with a selected target and evaluated.

In an embodiment, the proximal domain has at least 60, 70, 80, 85 90 or 95% homology with, or differs by no more than 1, 2, 3, 4, 5, or 6 nucleotides from, a reference proximal domain, e.g., a naturally occurring, e.g., an S. pyogenes, S. aureus or S. thermophilus, proximal domain, or a proximal domain described herein, e.g., from FIGS. 1A-1G. The Tail Domain

In an embodiment, the tail domain is 10+/−5, 20+/−5, 30+/−5, 40+/−5, 50+/−5, 60+/−5, 70+/−5, 80+/−5, 90+/−5, or 100+/−5 nucleotides, in length.

In an embodiment, the tail domain is 20+/−5 nucleotides in length.

In an embodiment, the tail domain is 20+/−10, 30+/−10, 40+/−10, 50+/−10, 60+/−10, 70+/−10, 80+/−10, 90+/−10, or 100+/−10 nucleotides, in length.

In an embodiment, the tail domain is 25+/−10 nucleotides in length.

In an embodiment, the tail domain is 10 to 100, 10 to 90, 10 to 80, 10 to 70, 10 to 60, 10 to 50, 10 to 40, 10 to 30, 10 to 20 or 10 to 15 nucleotides in length.

In another embodiment, the tail domain is 20 to 100, 20 to 90, 20 to 80, 20 to 70, 20 to 60, 20 to 50, 20 to 40, 20 to 30, or 20 to 25 nucleotides in length.

In an embodiment, the tail domain is 1 to 20, 1 to 15, 1 to 10, or 1 to 5 nucleotides in length.

In an embodiment, the tail domain nucleotides do not comprise modifications, e.g., modifications of the type provided in Section VIII. However, in an embodiment, the tail domain comprises one or more modifications, e.g., modifications that it render it less susceptible to degradation or more bio-compatible, e.g., less immunogenic. By way of example, the backbone of the tail domain can be modified with a phosphorothioate, or other modification(s) from Section VIII. In an embodiment a nucleotide of the tail domain can comprise a 2′ modification (e.g., a modification at the 2′ position on ribose), e.g., a 2-acetylation, e.g., a 2′ methylation, or other modification(s) from Section VIII.

In an embodiment, the tail domain can have as many as 1, 2, 3, 4, 5, 6, 7 or 8 modifications. In an embodiment, the target domain comprises as many as 1, 2, 3, or 4 modifications within 5 nucleotides of its 5′ end. In an embodiment, the target domain comprises as many as 1, 2, 3, or 4 modifications within 5 nucleotides of its 3′ end.

In an embodiment, the tail domain comprises a tail duplex domain, which can form a tail duplexed region. In an embodiment, the tail duplexed region can be 3, 4, 5, 6, 7, 8, 9, 10, 11, or 12 base pairs in length. In an embodiment, a further single stranded domain, exists 3′ to the tail duplexed domain. In an embodiment, this domain is 3, 4, 5, 6, 7, 8, 9, or 10 nucleotides in length. In an embodiment it is 4 to 6 nucleotides in length.

In an embodiment, the tail domain has at least 60, 70, 80, or 90% homology with, or differs by no more than 1, 2, 3, 4, 5, or 6 nucleotides from, a reference tail domain, e.g., a naturally occurring, e.g., an S. pyogenes, S. aureus or S. thermophilus, tail domain, or a tail domain described herein, e.g., from FIGS. 1A-1G.

In an embodiment, the proximal and tail domain, taken together comprise the following sequences:

(SEQ ID NO: 33) AAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCACCGAGUCGGUGCU, or (SEQ ID NO: 34) AAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCACCGAGUCGGUGGUG C, or (SEQ ID NO: 35) AAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCACCGAGUCGGUGCGGA UC, or (SEQ ID NO: 36) AAGGCUAGUCCGUUAUCAACUUGAAAAAGUG, or (SEQ ID NO: 37) AAGGCUAGUCCGUUAUCA, or (SEQ ID NO: 38) AAGGCUAGUCCG.

In an embodiment, the tail domain comprises the 3′ sequence UUUUUU, e.g., if a U6 promoter is used for transcription.

In an embodiment, the tail domain comprises the 3′ sequence UUUU, e.g., if an H1 promoter is used for transcription.

In an embodiment, tail domain comprises variable numbers of 3′ Us depending, e.g., on the termination signal of the pol-III promoter used.

In an embodiment, the tail domain comprises variable 3′ sequence derived from the DNA template if a T7 promoter is used.

In an embodiment, the tail domain comprises variable 3′ sequence derived from the DNA template, e.g., if in vitro transcription is used to generate the RNA molecule.

In an embodiment, the tail domain comprises variable 3′ sequence derived from the DNA template, e., if a pol-II promoter is used to drive transcription.

Modifications in the tail domain can be selected to not interfere with targeting efficacy, which can be evaluated by testing a candidate modification in the system described in Section IV. gRNAs having a candidate tail domain having a selected length, sequence, degree of complementarity, or degree of modification, can be evaluated in the system described in Section IV. The candidate tail domain can be placed, either alone, or with one or more other candidate changes in a gRNA molecule/Cas9 molecule system known to be functional with a selected target and evaluated.

In an embodiment, the tail domain comprises modifications at two consecutive nucleotides, e.g., two consecutive nucleotides that are within 5 nucleotides of the 5′ end of the tail domain, within 5 nucleotides of the 3′ end of the tail domain, or more than 5 nucleotides away from one or both ends of the tail domain. In an embodiment, no two consecutive nucleotides are modified within 5 nucleotides of the 5′ end of the tail domain, within 5 nucleotides of the 3′ end of the tail domain, or within a region that is more than 5 nucleotides away from one or both ends of the tail domain. In an embodiment, no nucleotide is modified within 5 nucleotides of the 5′ end of the tail domain, within 5 nucleotides of the 3′ end of the tail domain, or within a region that is more than 5 nucleotides away from one or both ends of the tail domain.

In an embodiment a gRNA has the following structure:

5′ [targeting domain]-[first complementarity domain]-[linking domain]-[second complementarity domain]-[proximal domain]-[tail domain]-3′

wherein, the targeting domain comprises a core domain and optionally a secondary domain, and is 10 to 50 nucleotides in length;

the first complementarity domain is 5 to 25 nucleotides in length and, In an embodiment has at least 50, 60, 70, 80, 85, 90 or 95% homology with a reference first complementarity domain disclosed herein;

the linking domain is 1 to 5 nucleotides in length;

the second complementarity domain is 5 to 27 nucleotides in length and, in an embodiment has at least 50, 60, 70, 80, 85, 90 or 95% homology with a reference second complementarity domain disclosed herein;

the proximal domain is 5 to 20 nucleotides in length and, in an embodiment has at least 50, 60, 70, 80, 85, 90 or 95% homology with a reference proximal domain disclosed herein; and

the tail domain is absent or a nucleotide sequence is 1 to 50 nucleotides in length and, in an embodiment has at least 50, 60, 70, 80, 85, 90 or 95% homology with a reference tail domain disclosed herein.

Exemplary Chimeric gRNAs

In an embodiment, a unimolecular, or chimeric, gRNA comprises, preferably from 5′ to 3′:

-   -   a targeting domain (which is complementary to a target nucleic         acid);     -   a first complementarity domain, e.g., comprising 15, 16, 17, 18,         19, 20, 21, 22, 23, 24, 25, or 26 nucleotides;     -   a linking domain;     -   a second complementarity domain (which is complementary to the         first complementarity domain);     -   a proximal domain; and a tail domain,     -   wherein,     -   (a) the proximal and tail domain, when taken together, comprise         at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53         nucleotides;     -   (b) there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49,         50, or 53 nucleotides 3′ to the last nucleotide of the second         complementarity domain; or     -   (c) there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50,         51, or 54 nucleotides 3′ to the last nucleotide of the second         complementarity domain that is complementary to its         corresponding nucleotide of the first complementarity domain.

In an embodiment, the sequence from (a), (b), or (c), has at least 60, 75, 80, 85, 90, 95, or 99% homology with the corresponding sequence of a naturally occurring gRNA, or with a gRNA described herein.

In an embodiment, the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides (e.g., 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, or 26 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 16 nucleotides (e.g., 16 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 17 nucleotides (e.g., 17 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 17 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 18 nucleotides (e.g., 18 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 18 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 19 nucleotides (e.g., 19 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 19 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 20 nucleotides (e.g., 20 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 20 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 21 nucleotides (e.g., 21 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 21 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 22 nucleotides (e.g., 22 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 22 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 23 nucleotides (e.g., 23 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 23 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 24 nucleotides (e.g., 24 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 24 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 25 nucleotides (e.g., 25 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 25 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 26 nucleotides (e.g., 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 26 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 16 nucleotides (e.g., 16 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 16 nucleotides (e.g., 16 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 16 nucleotides (e.g., 16 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 17 nucleotides (e.g., 17 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 17 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 17 nucleotides (e.g., 17 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 17 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 17 nucleotides (e.g., 17 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 17 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 18 nucleotides (e.g., 18 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 18 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 18 nucleotides (e.g., 18 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 18 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 18 nucleotides (e.g., 18 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 18 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 19 nucleotides (e.g., 19 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 19 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 19 nucleotides (e.g., 19 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 19 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 19 nucleotides (e.g., 19 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 19 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 20 nucleotides (e.g., 20 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 20 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 20 nucleotides (e.g., 20 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 20 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 20 nucleotides (e.g., 20 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 20 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 21 nucleotides (e.g., 21 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 21 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 21 nucleotides (e.g., 21 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 21 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 21 nucleotides (e.g., 21 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 21 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 22 nucleotides (e.g., 22 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 22 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 22 nucleotides (e.g., 22 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 22 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 22 nucleotides (e.g., 22 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 22 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 23 nucleotides (e.g., 23 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 23 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 23 nucleotides (e.g., 23 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 23 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 23 nucleotides (e.g., 23 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 23 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 24 nucleotides (e.g., 24 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 24 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 24 nucleotides (e.g., 24 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 24 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 24 nucleotides (e.g., 24 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 24 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 25 nucleotides (e.g., 25 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 25 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 25 nucleotides (e.g., 25 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 25 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 25 nucleotides (e.g., 25 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 25 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 26 nucleotides (e.g., 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 26 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 26 nucleotides (e.g., 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 26 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 26 nucleotides (e.g., 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 26 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the unimolecular, or chimeric, gRNA molecule (comprising a targeting domain, a first complementary domain, a linking domain, a second complementary domain, a proximal domain and, optionally, a tail domain) comprises the following sequence in which the targeting domain is depicted as 20 Ns but could be any sequence and range in length from 16 to 26 nucleotides and in which the gRNA sequence is followed by 6 Us, which serve as a termination signal for the U6 promoter, but which could be either absent or fewer in number: NNNNNNNNNNNNNNNNNNNNGUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGG CUAGUCCGUUAUCAACUUGAAAAAGUGGCACCGAGUCGGUGCUUUUUU (SEQ ID NO: 45). In an embodiment, the unimolecular, or chimeric, gRNA molecule is a S. pyogenes gRNA molecule.

In some embodiments, the unimolecular, or chimeric, gRNA molecule (comprising a targeting domain, a first complementary domain, a linking domain, a second complementary domain, a proximal domain and, optionally, a tail domain) comprises the following sequence in which the targeting domain is depicted as 20 Ns but could be any sequence and range in length from 16 to 26 nucleotides and in which the gRNA sequence is followed by 6 Us, which serve as a termination signal for the U6 promoter, but which could be either absent or fewer in number: NNNNNNNNNNNNNNNNNNNNGUUUUAGUACUCUGGAAACAGAAUCUACUAAAAC AAGGCAAAAUGCCGUGUUUAUCUCGUCAACUUGUUGGCGAGAUUUUUU (SEQ ID NO: 40). In an embodiment, the unimolecular, or chimeric, gRNA molecule is a S. aureus gRNA molecule.

The sequences and structures of exemplary chimeric gRNAs are also shown in FIGS. 1H-11 .

Exemplary Modular gRNAs

In an embodiment, a modular gRNA comprises:

-   -   a first strand comprising, preferably from 5′ to 3′;         -   a targeting domain, e.g., comprising 15, 16, 17, 18, 19, 20,             21, 22, 23, 24, 25, or 26 nucleotides;         -   a first complementarity domain; and         -   a second strand, comprising, preferably from 5′ to 3′:         -   optionally a 5′ extension domain;         -   a second complementarity domain;         -   a proximal domain; and         -   a tail domain,     -   wherein:     -   (a) the proximal and tail domain, when taken together, comprise         at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53         nucleotides;     -   (b) there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49,         50, or 53 nucleotides 3′ to the last nucleotide of the second         complementarity domain; or     -   (c) there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50,         51, or 54 nucleotides 3′ to the last nucleotide of the second         complementarity domain that is complementary to its         corresponding nucleotide of the first complementarity domain.

In an embodiment, the sequence from (a), (b), or (c), has at least 60, 75, 80, 85, 90, 95, or 99% homology with the corresponding sequence of a naturally occurring gRNA, or with a gRNA described herein.

In an embodiment, the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides (e.g., 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16, 17, 18, 19, 20, 21, 22, 23, 24, 25 or 26 nucleotides in length. In an embodiment, the targeting domain comprises, has, or consists of, 16 nucleotides (e.g., 16 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16 nucleotides in length.

In an embodiment, the targeting domain has, or consists of, 17 nucleotides (e.g., 17 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 17 nucleotides in length.

In an embodiment, the targeting domain has, or consists of, 18 nucleotides (e.g., 18 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 18 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 19 nucleotides (e.g., 19 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 19 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 20 nucleotides (e.g., 20 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 20 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 21 nucleotides (e.g., 21 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 21 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 22 nucleotides (e.g., 22 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 22 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 23 nucleotides (e.g., 23 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 23 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 24 nucleotides (e.g., 24 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 24 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 25 nucleotides (e.g., 25 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 5 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 26 nucleotides (e.g., 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 26 nucleotides in length.

In an embodiment, the targeting domain comprises, has, or consists of, 16 nucleotides (e.g., 16 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 16 nucleotides (e.g., 16 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 16 nucleotides (e.g., 16 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 16 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain has, or consists of, 17 nucleotides (e.g., 17 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 17 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain has, or consists of, 17 nucleotides (e.g., 17 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 17 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain has, or consists of, 17 nucleotides (e.g., 17 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 17 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain has, or consists of, 18 nucleotides (e.g., 18 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 18 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain has, or consists of, 18 nucleotides (e.g., 18 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 18 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain has, or consists of, 18 nucleotides (e.g., 18 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 18 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 19 nucleotides (e.g., 19 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 19 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 19 nucleotides (e.g., 19 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 19 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 19 nucleotides (e.g., 19 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 19 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 20 nucleotides (e.g., 20 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 20 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 20 nucleotides (e.g., 20 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 20 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 20 nucleotides (e.g., 20 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 20 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 21 nucleotides (e.g., 21 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 21 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 21 nucleotides (e.g., 21 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 21 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 21 nucleotides (e.g., 21 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 21 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 22 nucleotides (e.g., 22 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 22 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 22 nucleotides (e.g., 22 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 22 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 22 nucleotides (e.g., 22 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 22 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 23 nucleotides (e.g., 23 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 23 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 23 nucleotides (e.g., 23 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 23 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 23 nucleotides (e.g., 23 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 23 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 24 nucleotides (e.g., 24 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 24 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 24 nucleotides (e.g., 24 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 24 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 24 nucleotides (e.g., 24 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 24 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 25 nucleotides (e.g., 25 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 25 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 25 nucleotides (e.g., 25 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 25 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 25 nucleotides (e.g., 25 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 25 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 26 nucleotides (e.g., 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 26 nucleotides in length; and the proximal and tail domain, when taken together, comprise at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides.

In an embodiment, the targeting domain comprises, has, or consists of, 26 nucleotides (e.g., 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 26 nucleotides in length; and there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53 nucleotides 3′ to the last nucleotide of the second complementarity domain.

In an embodiment, the targeting domain comprises, has, or consists of, 26 nucleotides (e.g., 26 consecutive nucleotides) having complementarity with the target domain, e.g., the targeting domain is 26 nucleotides in length; and there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54 nucleotides 3′ to the last nucleotide of the second complementarity domain that is complementary to its corresponding nucleotide of the first complementarity domain.

II. Methods for Designing gRNAs

Methods for designing gRNAs are described herein, including methods for selecting, designing and validating target domains. Exemplary targeting domains are also provided herein. Targeting Domains discussed herein can be incorporated into the gRNAs described herein.

Methods for selection and validation of target sequences as well as off-target analyses are described, e.g., in Mali et al., 2013 Science 339(6121): 823-826; Hsu et al. Nat Biotechnol, 31(9): 827-32; Fu et al., 2014 Nat Biotechnol, doi: 10.1038/nbt.2808. PubMed PMID: 24463574; Heigwer et al., 2014 Nat Methods 11(2):122-3. doi: 10.1038/nmeth.2812. PubMed PMID: 24481216; Bae et al., 2014 Bioinformatics PubMed PMID: 24463181; Xiao A et al., 2014 Bioinformatics PubMed PMID: 24389662.

For example, a software tool can be used to optimize the choice of gRNA within a user's target sequence, e.g., to minimize total off-target activity across the genome. Off target activity may be other than cleavage. For each possible gRNA choice using S. pyogenes Cas9, software tools can identify all potential off-target sequences (preceding either NAG or NGG PAMs) across the genome that contain up to a certain number (e.g., 1, 2, 3, 4, 5, 6, 7, 8, 9, or 10) of mismatched base-pairs. The cleavage efficiency at each off-target sequence can be predicted, e.g., using an experimentally-derived weighting scheme. Each possible gRNA can then ranked according to its total predicted off-target cleavage; the top-ranked gRNAs represent those that are likely to have the greatest on-target and the least off-target cleavage. Other functions, e.g., automated reagent design for gRNA vector construction, primer design for the on-target Surveyor assay, and primer design for high-throughput detection and quantification of off-target cleavage via next-generation sequencing, can also be included in the tool. Candidate gRNA molecules can be evaluated by art-known methods or as described in Section IV herein.

Guide RNAs (gRNAs) for use with S. pyogenes, S. aureus and N. meningitidis Cas9s were identified using a DNA sequence searching algorithm. Guide RNA design was carried out using a custom guide RNA design software based on the public tool cas-offinder (reference:Cas-OFFinder: a fast and versatile algorithm that searches for potential off-target sites of Cas9 RNA-guided endonucleases., Bioinformatics. 2014 Feb. 17. Bae S, Park J, Kim J S. PMID:24463181). Said custom guide RNA design software scores guides after calculating their genomewide off-target propensity. Typically matches ranging from perfect matches to 7 mismatches are considered for guides ranging in length from 17 to 24. Once the off-target sites are computationally determined, an aggregate score is calculated for each guide and summarized in a tabular output using a web-interface. In addition to identifying potential gRNA sites adjacent to PAM sequences, the software also identifies all PAM adjacent sequences that differ by 1, 2, 3 or more nucleotides from the selected gRNA sites. Genomic DNA sequence for each gene was obtained from the UCSC Genome browser and sequences were screened for repeat elements using the publically available RepeatMasker program. RepeatMasker searches input DNA sequences for repeated elements and regions of low complexity. The output is a detailed annotation of the repeats present in a given query sequence.

Following identification, gRNAs were ranked into tiers based on their distance to the target site, their orthogonality or presence of a 5′ G (based on identification of close matches in the human genome containing a relavant PAM (e.g., in the case of S. pyogenes, a NGG PAM, in the case of S. aureus, a NNGRRT or NNGRRV PAM, and in the case of N. meningitidis, a NNNNGATT or NNNNGCTT PAM). Orthogonality refers to the number of sequences in the human genome that contain a minimum number of mismatches to the target sequence. A “high level of orthogonality” or “good orthogonality” may, for example, refer to 20-mer gRNAs that have no identical sequences in the human genome besides the intended target, nor any sequences that contain one or two mismatches in the target sequence. Targeting domains with good orthogonality are selected to minimize off-target DNA cleavage.

As an example, for S. pyogenes and N. meningitidis targets, 17-mer, or 20-mer gRNAs were designed. As another example, for S. aureus targets, 18-mer, 19-mer, 20-mer, 21-mer, 22-mer, 23-mer and 24-mer gRNAs were designed. Targeting domains, disclosed herein, may comprise the 17-mer described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, e.g., the targeting domains of 18 or more nucleotides may comprise the 17-mer gRNAs described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. Targeting domains, disclosed herein, may comprises the 18-mer described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, e.g., the targeting domains of 19 or more nucleotides may comprise the 18-mer gRNAs described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. Targeting domains, disclosed herein, may comprises the 19-mer described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, e.g., the targeting domains of 20 or more nucleotides may comprise the 19-mer gRNAs described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. Targeting domains, disclosed herein, may comprises the 20-mer gRNAs described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, e.g., the targeting domains of 21 or more nucleotides may comprise the 20-mer gRNAs described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. Targeting domains, disclosed herein, may comprises the 21-mer described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, e.g., the targeting domains of 22 or more nucleotides may comprise the 21-mer gRNAs described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. Targeting domains, disclosed herein, may comprises the 22-mer described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, e.g., the targeting domains of 23 or more nucleotides may comprise the 22-mer gRNAs described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. Targeting domains, disclosed herein, may comprises the 23-mer described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, e.g., the targeting domains of 24 or more nucleotides may comprise the 23-mer gRNAs described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31. Targeting domains, disclosed herein, may comprises the 24-mer described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31, e.g., the targeting domains of 25 or more nucleotides may comprise the 24-mer gRNAs described in Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 15 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31.

gRNAs were identified for both single-gRNA nuclease cleavage and for a dual-gRNA paired “nickase” strategy. Criteria for selecting gRNAs and the determination for which gRNAs can be used for the dual-gRNA paired “nickase” strategy is based on two considerations:

-   -   1. gRNA pairs should be oriented on the DNA such that PAMs are         facing out and cutting with the D10A Cas9 nickase will result in         5′ overhangs.     -   2. An assumption that cleaving with dual nickase pairs will         result in deletion of the entire intervening sequence at a         reasonable frequency. However, cleaving with dual nickase pairs         can also result in indel mutations at the site of only one of         the gRNAs. Candidate pair members can be tested for how         efficiently they remove the entire sequence versus causing indel         mutations at the site of one gRNA.

The targeting domains discussed herein can be incorporated into the gRNAs described herein.

Strategies to Identify gRNAs for S. pyogenes, S. aureus, and N. meningitidis to Correct a Mutation in the HBB Gene

gRNAs were designed for use with S. pyogenes, and S. aureus Cas9 enzymes to target the E6V mutation in the HBB gene. As an example, three strategies were utilized to identify gRNAs for use with S. pyogenes, S. aureus and N. meningitidis Cas9 enzymes.

In one strategy, the gRNAs were identified and ranked into 3 tiers for S. pyogenes (Tables 1A-1C). The targeting domains for tier 1 gRNA molecules for use with the S. pyogenes Cas9 to target the E6V mutation in the HBB gene were selected based on (1) a reasonable distance to the target position, and (2) a high level of orthogonality. Tier 2 gRNAs were selected based on (1), a reasonable distance to the target position, and (2) presence of a 5′G. Tier 3 used the same distance restriction, but removed the requirement of good orthogonality and the 5′G. Note that tiers are non-inclusive (each gRNA is listed only once). gRNAs for use with the S. aureus (Table 1D), Cas9s were identified manually by scanning genomic DNA sequence for the presence of PAM sequences. These gRNAs were not separated into tiers, but were listed in a single list.

In a second strategy, the gRNAs were identified and ranked into 4 tiers for S. pyogenes (Tables 13A-13D) and 5 tiers for S. aureus (Tables 14A-14C). The targeting domain for tier 1 gRNA molecules to use with S. pyogenes Cas9 were selected based on (1) a short distance to the target position, e.g., within 100 bp upstream and 100 bp downstream of the mutation, (2) a high level of orthogonality, and (3) the presence of a 5′ G. For selection of tier 2 gRNAs, a short distance and high orthogonality were required but the presence of a 5′G was not required. Tier 3 uses the same distance restriction and the requirement for a 5′G, but removes the requirement of good orthogonality. Tier 4 uses the same distance restriction but removes the requirement of good orthogonality and the 5′G. The targeting domain for tier 1 gRNA molecules to use with S. aureus Cas9 were selected based on (1) a short distance to the target position, e.g., within 100 bp upstream and 100 bp downstream of the mutation, (2) a high level of orthogonality, and (3) the presence of a 5′ G. For selection of tier 2 gRNAs, a short distance and high orthogonality were required but the presence of a 5′G was not required. Tier 3 uses the same distance restriction and the requirement for a 5′G, but removes the requirement of good orthogonality. Tier 4 uses the same distance restriction but removes the requirement of good orthogonality and the 5′G. Tier 5 is selected based on (1) a short distance to the target position, e.g., within 100 bp upstream and 100 bp downstream of the mutation and (2) PAM is NNGRRV. Note that tiers are non-inclusive (each gRNA is listed only once for the strategy). In certain instances, no gRNA was identified based on the criteria of the particular tier. In some instances, there are no corresponding exemplary gRNAs in certain tiers.

In a third strategy, the gRNAs were identified and ranked into 3 tiers for S. pyogenes (Tables 24A-24D), 4 tiers for S. aureus (Tables 25A-25B) and 3 tiers for N. meningitidis (Tables 26). The targeting domain for tier 1 gRNA molecules to use with S. pyogenes Cas9 were selected based on (1) distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation and (2) a high level of orthogonality. The targeting domain for tier 2 gRNA molecules to use with S. pyogenes Cas9 were selected based on (1) distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation and (2) the presence of a 5′G. The targeting domain for tier 3 gRNA molecules to use with S. pyogenes Cas9 were selected based on distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation. The targeting domain for tier 1 gRNA molecules to use with S. aureus Cas9 were selected based on (1) distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation, (2) a high level of orthogonality and (3) PAM is NNGRRT. The targeting domain for tier 2 gRNA molecules to use with S. aureus Cas9 were selected based on (1) distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation, (2) the presence of a 5′G, and (3) PAM is NNGRRT. The targeting domain for tier 3 gRNA molecules to use with S. aureus Cas9 were selected based on (1) distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation and (2) PAM is NNGRRT. The targeting domain for tier 4 gRNA molecules to use with S. aureus Cas9 were selected based on (1) distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation and (2) PAM is NNGRRV. The targeting domain for tier 1 gRNA molecules to use with N. meningitidis Cas9 were selected based on (1) distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation and (2) a high level of orthogonality. The targeting domain for tier 2 gRNA molecules to use with N. meningitidis Cas9 were selected based on (1) distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation and (2) the presence of a 5′G. The targeting domain for tier 3 gRNA molecules to use with N. meningitidis Cas9 were selected based on distance to the target position, e.g., within 200 bp upstream and 200 bp downstream of the mutation.

In an embodiment, dual targeting (e.g., dual nicking) is used to create two nicks on opposite DNA strands by using S. pyogenes, S. aureus and N. meningitidis Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. Exemplary nickase pairs including selecting a targeting domain from Group A and a second targeting domain from Group B in Table 24D (for S. pyogenes). It is contemplated herein that in an embodiment a targeting domain of Group A can be combined with any of the targeting domains of Group B in Table 24D (for S. pyogenes). For example, HBB-9, HBB-20can be combined with HBB-11, HBB-39.

Strategies to Identify gRNAs for S. pyogenes, S. aureus, and N. meningitidis to Knock Out the BCL11A Gene

gRNAs were designed for use with S. pyogenes, S. aureus and N. meningitidis Cas9 enzymes to induce an insertion or deletion of one or more nucleotides mediated by NHEJ in close proximity to or within the early coding region. As an example, three strategies were utilized to identify gRNAs for use with S. pyogenes, S. aureus and N. meningitidis Cas9 enzymes.

In one strategy, the gRNAs were identified and ranked into 4 tires for S. pyogenes (Tables 2A-2D). The targeting domains for tier 1 gRNA molecules for use with the S. pyogenes Cas9 to knockout the BCL11A gene were selected based on (1) a reasonable distance to the target position, and (2) a high level of orthogonality. Tier 2 gRNAs were selected based on (1), a reasonable distance to the target position, and (2) presence of a 5′G. Tier 3 used the same distance restriction, but removed the requirement of good orthogonality and the 5′G. Tier 4 only required the presence in the coding sequence. Note that tiers are non-inclusive (each gRNA is listed only once). gRNAs for use with the S. aureus (Table 2E), and N. meningitidis (Table 2F) Cas9s were identified manually by scanning genomic DNA sequence for the presence of PAM sequences. These gRNAs were not separated into tiers, but were listed in a single list. Note that tiers are non-inclusive (each gRNA is listed only once for the strategy). In certain instances, no gRNA was identified based on the criteria of the particular tier.

In a second strategy, the gRNAs were identified and ranked into 5 tiers for S. pyogenes (Tables 4A-4E), and S. aureus (Tables 5A-5E); and 2 tiers for N. meningitidis (Tables 6A-6B). For S. pyogenes, and S. aureus, the targeting domain for tier 1 gRNA molecules were selected based on (1) distance to a target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon), (2) a high level of orthogonality and (3) the presence of 5′G. The targeting domain for tier 2 gRNA molecules were selected based on (1) distance to a target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon) and (2) a high level of orthogonality. The targeting domain for tier 3 gRNA molecules were selected based on (1) distance to a target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon) and (2) the presence of 5′G. The targeting domain for tier 4 gRNA molecules were selected based on distance to a target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon). The targeting domain for tier 5 gRNA molecules were selected based on distance to the target site (e.g., start codon), e.g., within reminder of the coding sequence, e.g., downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon). For N. meningitidis, the targeting domain for tier 1 gRNA molecules were selected based on (1) distance to a target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon). The targeting domain for tier 2 gRNA molecules were selected based on distance to the target site (e.g., start codon), e.g., within reminder of the coding sequence, e.g., downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon). Note that tiers are non-inclusive (each gRNA is listed only once for the strategy). In certain instances, no gRNA was identified based on the criteria of the particular tier.

In a third strategy, the gRNAs were identified and ranked into 3 tiers for S. pyogenes (Tables 15A-15D), and N. meningitidis (Tables 17A-17B); and 5 tiers for S. aureus (Tables 16A-16D). The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 1 gRNA molecules were selected based on (1) distance to a target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon) and (2) a high level of orthogonality. The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 2 gRNA molecules were selected based on (1) distance to the target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon). The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 3 gRNA molecules were selected based on distance to the target site (e.g., start codon), e.g., within reminder of the coding sequence, e.g., downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon). The gRNAs were identified and ranked into 5 tiers for S. aureus, when the relevant PAM was NNGRRT or NNGRRV. The targeting domain to be used with S. aureus Cas9 enzymes for tier 1 gRNA molecules were selected based on (1) distance to the target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon), (2) a high level of orthogonality, and (3) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 2 gRNA molecules were selected based on (1) distance to the target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon), and (2) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 3 gRNA molecules were selected based on (1) distance to a the target site (e.g., start codon) mutation, e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon), and (2) PAM is NNGRRV. The targeting domain to be used with S. aureus Cas9 enzymes for tier 4 gRNA molecules were selected based on (1) distance to the target site (e.g., start codon), e.g., within reminder of the coding sequence, e.g., downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon), and (2) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 5 gRNA molecules were selected based on (1) distance to the target site (e.g., start codon), e.g., within reminder of the coding sequence, e.g., downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon), and (2) PAM is NNGRRV. The gRNAs were identified and ranked into 3 tiers for N. meningitidis. The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 1 gRNA molecules were selected based on (1) distance to the target site, e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon) and (2) a high level of orthogonality. The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 2 gRNA molecules were selected based on (1) distance to the target site (e.g., start codon), e.g., within 500 bp (e.g., downstream) of the target site (e.g., start codon). The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 3 gRNA molecules were selected based on distance to the target site (e.g., start codon), e.g., within reminder of the coding sequence, e.g., downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon). Note that tiers are non-inclusive (each gRNA is listed only once for the strategy). In certain instances, no gRNA was identified based on the criteria of the particular tier.

In an embodiment, when a single gRNA molecule is used to target a Cas9 nickase to create a single strand break in close proximity to the BCL11A target position, e.g., the gRNA is used to target either upstream of (e.g., within 500 bp, e.g., within 200 bp upstream of the BCL11A target position), or downstream of (e.g., within 500 bp, e.g., within 200 bp downstream of the BCL11A target position) in the BCL11A gene.

In an embodiment, when a single gRNA molecule is used to target a Cas9 nuclease to create a double strand break to in close proximity to the BCL11A target position, e.g., the gRNA is used to target either upstream of (e.g., within 500 bp, e.g., within 200 bp upstream of the BCL11A target position), or downstream of (e.g., within 500 bp, e.g., within 200 bp downstream of the BCL11A target position) in the BCL11A gene.

In an embodiment, dual targeting is used to create two double strand breaks to in close proximity to the mutation, e.g., the gRNA is used to target either upstream of (e.g., within 500 bp, e.g., within 200 bp upstream of the BCL11A target position), or downstream of (e.g., within 500 bp, e.g., within 200 bp downstream of the BCL11A target position) in the BCL11A gene. In an embodiment, the first and second gRNAs are used to target two Cas9 nucleases to flank, e.g., the first of gRNA is used to target upstream of (e.g., within 500 bp, e.g., within 200 bp upstream of the BCL11A target position), and the second gRNA is used to target downstream of (e.g., within 500 bp, e.g., within 200 bp downstream of the BCL11A target position) in the BCL11A gene.

In an embodiment, dual targeting is used to create a double strand break and a pair of single strand breaks to delete a genomic sequence including the BCL11A target position. In an embodiment, the first, second and third gRNAs are used to target one Cas9 nuclease and two Cas9 nickases to flank, e.g., the first gRNA that will be used with the Cas9 nuclease is used to target upstream of (e.g., within 500 bp, e.g., within 200 bp upstream of the BCL11A target position) or downstream of (e.g., within 500 bp, e.g., within 200 bp downstream of the BCL11A target position), and the second and third gRNAs that will be used with the Cas9 nickase pair are used to target the opposite side of the mutation (e.g., within 200 bp upstream or downstream of the BCL11A target position) in the BCL11A gene.

In an embodiment, when four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four single strand breaks to delete genomic sequence including the mutation, the first pair and second pair of gRNAs are used to target four Cas9 nickases to flank, e.g., the first pair of gRNAs are used to target upstream of (e.g., within 500 bp, e.g., within 200 bp upstream of the BCL11A target position), and the second pair of gRNAs are used to target downstream of (e.g., within 500 bp, e.g., within 200 bp downstream of the BCL11A target position) in the BCL11A gene.

In an embodiment, dual targeting (e.g., dual nicking) is used to create two nicks on opposite DNA strands by using S. pyogenes, S. aureus and N. meningitidis Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. Exemplary nickase pairs including selecting a targeting domain from Group A and a second targeting domain from Group B, or including selecting a targeting domain from Group C and a second targeting domain from Group D in Table 15D (for S. pyogenes). It is contemplated herein that in an embodiment a targeting domain of Group A can be combined with any of the targeting domains of Group B; in an embodiment a targeting domain of Group C can be combined with any of the targeting domains of Group D in Table 15D (for S. pyogenes). For example, BCL11A-5355 or BCL11A-5380 can be combined with BCL11A-5321 or BCL11A-5416; or BCL11A-5333, BCL11A-5354, or BCL11A-5329 can be combined with BCL11A-5367 or BCL11A-5341.

Strategies to Identify gRNAs for S. pyogenes, S. aureus, and N. meningitidis to Knock Down the BCL11A Gene

gRNAs were designed for use with S. pyogenes, S. aureus and N. meningitidis one or more Cas9 molecules, e.g., enzymatically inactive Cas9 (eiCas9) molecules or Cas9 fusion proteins (e.g., an eiCas9 fused to a transcription repressor domain or chromatin modifying protein to alter (e.g., to block, reduce, or decrease) the transcription of the BCL11A gene. As an example, three strategies were utilized to identify gRNAs for use with S. pyogenes, S. aureus and N. meningitidis one or more Cas9 molecules.

In one strategy, the targeting domains for gRNA molecules to knockdown the BCL11A gene were designed to target the 1 kb of sequence 3′ of the start codon. They were listed in a single list for S. pyogenes (Table 3A), S. aureus (Table 3B) and N. meningitidis (Table 3C).

In a second strategy, the gRNAs were identified and ranked into 4 tiers for S. pyogenes (Tables 10A-10D), and S. aureus (Tables 11A-11D). The gRNAs were identified and listed in a single list for N. meningitidis (Table 12). For S. pyogenes, and S. aureus, the targeting domain for tier 1 gRNA molecules were selected based on (1) distance to a target site (e.g., a transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site), (2) a high level of orthogonality and (3) the presence of 5′G. The targeting domain for tier 2 gRNA molecules were selected based on (1) distance to a target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site) and (2) a high level of orthogonality. The targeting domain for tier 3 gRNA molecules were selected based on (1) distance to a target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site) and (2) the presence of 5′G. The targeting domain for tier 4 gRNA molecules were selected based on distance to a target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site).

In a third strategy, gRNAs were designed for use with S. pyogenes, S. aureus and N. meningitidis Cas9 molecules. The gRNAs were identified and ranked into 3 tiers for S. pyogenes (Tables 18A-18C). The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 1 gRNA molecules were selected based on (1) distance to a target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site) and (2) a high level of orthogonality. The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 2 gRNA molecules were selected based on (1) distance to the target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site). The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 3 gRNA molecules were selected based on distance to the target site (e.g., the transcription start site), e.g., within the additional 500 bp upstream and downstream of the transcription start site (i.e., extending to 1 kb upstream and downstream of the transcription start site. The gRNAs were identified and ranked into 5 tiers for S. aureus, when the relevant PAM was NNGRRT or NNGRRV (Tables 19A-19B). The targeting domain to be used with S. aureus Cas9 enzymes for tier 1 gRNA molecules were selected based on (1) distance to the target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site), (2) a high level of orthogonality, and (3) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 2 gRNA molecules were selected based on (1) distance to the target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site), and (2) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 3 gRNA molecules were selected based on (1) distance to a target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site), and (2) PAM is NNGRRV. The targeting domain to be used with S. aureus Cas9 enzymes for tier 4 gRNA molecules were selected based on (1) distance to the target site (e.g., the transcription start site), e.g., within the additional 500 bp upstream and downstream of the transcription start site (i.e., extending to 1 kb upstream and downstream of the transcription start site, and (2) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 5 gRNA molecules were selected based on (1) distance to the target site (e.g., the transcription start site), e.g., within the additional 500 bp upstream and downstream of the transcription start site (i.e., extending to 1 kb upstream and downstream of the transcription start site, and (2) PAM is NNGRRV. The gRNAs were identified and ranked into 3 tiers for N. meningitidis (Tables 20A-20C). The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 1 gRNA molecules were selected based on (1) distance to a target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site) and (2) a high level of orthogonality. The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 2 gRNA molecules were selected based on (1) distance to the target site (e.g., the transcription start site), e.g., within 500 bp (e.g., upstream or downstream) of the target site (e.g., the transcription start site). The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 3 gRNA molecules were selected based on distance to the target site (e.g., the transcription start site), e.g., within the additional 500 bp upstream and downstream of the transcription start site (i.e., extending to 1 kb upstream and downstream of the transcription start site. Note that tiers are non-inclusive (each gRNA is listed only once for the strategy). In certain instances, no gRNA was identified based on the criteria of the particular tier.

Strategies to Identify gRNAs for S. pyogenes, S. aureus, and N. meningitidis to Remove (e.g., Delete) the Enhancer Region the BCL11A Gene

gRNAs were designed for use with S. pyogenes, S. aureus and N. meningitidis Cas9 enzymes to remove (e.g., delete) the enhancer region in the BCL11A gene. As an example, two strategies were utilized to identify gRNAs for use with S. pyogenes, S. aureus and N. meningitidis one or more Cas9 molecules.

In an strategy, the gRNAs were identified and ranked into 4 tiers for S. pyogenes (Tables 7A-7D) and for S. aureus (Tables 8A-8D). The gRNAs were identified and listed in a single list for N. meningitidis (Table 9). The targeting domains for tier 1 gRNA molecules for use with the S. pyogenes, S. aureus Cas9 were selected based on (1) a reasonable distance to the target position, e.g., within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), (2) a high level of orthogonality and (3) presence of a 5′G. For selection of tier 2 gRNAs, reasonable distance and high orthogonality were required but the presence of a 5′G was not required. Tier 3 uses the same distance restriction and the requirement for a 5′G, but removes the requirement of good orthogonality. Tier 4 uses the same distance restriction but removes the requirement of good orthogonality and the 5′G. Note that tiers are non-inclusive (each gRNA is listed only once for the strategy). In certain instances, no gRNA was identified based on the criteria of the particular tier.

In a second strategy, gRNAs were designed for use with S. pyogenes, S. aureus and N. meningitidis Cas9 molecules. The gRNAs were identified and ranked into 4 tiers for S. pyogenes (Tables 21A-21E). The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 1 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), (2) a high level of orthogonality and (3) presence of 5′G. The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 2 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) and (2) a high level of orthogonality. The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 3 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) and (2) presence of 5′G. The targeting domain to be used with S. pyogenes Cas9 enzymes for tier 4 gRNA molecules were selected based on within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS). The gRNAs were identified and ranked into 5 tiers for S. aureus, when the relevant PAM was NNGRRT or NNGRRV (Tables 22A-22E). The targeting domain to be used with S. aureus Cas9 enzymes for tier 1 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), (2) a high level of orthogonality, (3)) presence of 5′G and (4) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 2 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), (2) a high level of orthogonality, and (3) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 3 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), (2) presence of 5′G and (3) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 4 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), and (2) PAM is NNGRRT. The targeting domain to be used with S. aureus Cas9 enzymes for tier 5 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), and (2) PAM is NNGRRV. The gRNAs were identified and ranked into 3 tiers for N. meningitidis (Tables 23A-23C). The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 1 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), (2) a high level of orthogonality and (3) presence of 5′G. The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 2 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) and (2) a high level of orthogonality. The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 3 gRNA molecules were selected based on (1) within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) and (2) presence of 5′G. The targeting domain to be used with N. meningitidis Cas9 enzymes for tier 4 gRNA molecules were selected based on within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS). Note that tiers are non-inclusive (each gRNA is listed only once for the strategy). In certain instances, no gRNA was identified based on the criteria of the particular tier.

In an embodiment, dual targeting (e.g., dual nicking) is used to create two nicks on opposite DNA strands by using S. pyogenes, S. aureus and N. meningitidis Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. Exemplary nickase pairs including selecting a targeting domain from Group A and a second targeting domain from Group B, or including selecting a targeting domain from Group C and a second targeting domain from Group D in Table 20E (for S. pyogenes). It is contemplated herein that in an embodiment a targeting domain of Group A can be combined with any of the targeting domains of Group B; in an embodiment a targeting domain of Group C can be combined with any of the targeting domains of Group D in Table 20E (for S. pyogenes). For example, BCL11A-13271 or BCL11A-13264 can be combined with BCL11A-13276; or BCL11A-13262 or BCL11A-13282 can be combined with BCL11A-13290 or BCL11A-13280.

In an embodiment, two or more (e.g., three or four) gRNA molecules are used with one Cas9 molecule. In another embodiment, when two or more (e.g., three or four) gRNAs are used with two or more Cas9 molecules, at least one Cas9 molecule is from a different species than the other Cas9 molecule(s). For example, when two gRNA molecules are used with two Cas9 molecules, one Cas9 molecule can be from one species and the other Cas9 molecule can be from a different species. Both Cas9 species are used to generate a single or double-strand break, as desired.

Any of the targeting domains in the tables described herein can be used with a Cas9 nickase molecule to generate a single strand break.

Any of the targeting domains in the tables described herein can be used with a Cas9 nuclease molecule to generate a double strand break.

When two gRNAs designed for use to target two Cas9 molecules, one Cas9 can be one species, the second Cas9 can be from a different species. Both Cas9 species are used to generate a single or double-strand break, as desired.

It is contemplated herein that any upstream gRNA described herein may be paired with any downstream gRNA described herein. When an upstream gRNA designed for use with one species of Cas9 is paired with a downstream gRNA designed for use from a different species of Cas9, both Cas9 species are used to generate a single or double-strand break, as desired.

Exemplary Targeting Domains

Table 1A provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the first tier parameters, and are selected based on the close proximity and orientation to mutation and orthogonality in the human genome. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a Cas9 molecule (e.g., a S. pyogenes Cas9 molecule) that gives double stranded cleavage. Any of the targeting domains in the table can be used with a Cas9 (e.g., a S. pyogenes Cas9 nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using Cas9 nickases (e.g., a S. pyogenes Cas9 nickase) with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position. In an embodiment, two 20-mer guide RNAs are used to target two Cas9 nucleases (e.g., two S. pyogenes Cas9 nucleases) or two Cas9 nickases (e.g., two S. pyogenes Cas9 nickases), e.g., HBB-8 and HBB-25 are used. In an embodiment, two 17-mer RNAs are used to target two Cas9 nucleases or two Cas9 nickases, e.g., HBB-35 and HBB-53 are used.

TABLE 1A Target SEQ 1st Tier DNA Site ID gRNA Name Strand Targeting Domain Length NO HBB-8 − AAGGUGAACGUGGAUGAAGU 20 387 HBB-25 + GUAACGGCAGACUUCUCCUC 20 388 HBB-35 − GUGAACGUGGAUGAAGU 17 389 HBB-53 + ACGGCAGACUUCUCCUC 17 390

Table 1B provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the second tier parameters and are selected based on the presence of a 5′ G and reasonable proximity to mutation. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that gives double stranded cleavage. Any of the targeting domains in the table can be used with S. pyogenes single-stranded break nucleases (nickases). In an embodiment, dual targeting is used to create two nicks. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position.

TABLE 1B Target SEQ 2nd Tier DNA Site ID gRNA Name Strand Targeting Domain Length NO HBB-12 − GAAGUUGGUGGUGAGGCCCU 20 391 HBB-1 − GCAACCUCAAACAGACACCA 20 392 HBB-52 + GCCCCACAGGGCAGUAA 17 393 HBB-32 − GCCGUUACUGCCCUGUG 17 394 HBB-46 − GGAGACCAAUAGAAACU 17 395 HBB-37 − GGAUGAAGUUGGUGGUG 17 396 HBB-29 − GGUGCAUCUGACUCCUG 17 397 HBB-4 − GUCUGCCGUUACUGCCCUGU 20 398 HBB-9 − GUGAACGUGGAUGAAGUUGG 20 399 HBB-34 − GUGGGGCAAGGUGAACG 17 400 HBB-40 − GUGGUGAGGCCCUGGGC 17 401 HBB-44 − GUUACAAGACAGGUUUA 17 402 HBB-51 + GUUCACCUUGCCCCACA 17 403 HBB-39 − GUUGGUGGUGAGGCCCU 17 404

Table 1C provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the third tier parameters and are selected based on reasonable proximity to mutation. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that gives double stranded cleavage. Any of the targeting domains in the table can be used with S. pyogenes single-stranded break nucleases (nickases). In an embodiment, dual targeting is used to create two nicks. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position.

TABLE 1C Target SEQ 3rd Tier DNA Site ID gRNA Name Strand Targeting Domain Length NO HBB-36 − AACGUGGAUGAAGUUGG 17 405 HBB-17 − AAGGUUACAAGACAGGUUUA 20 406 HBB-47 + ACAUGCCCAGUUUCUAU 17 407 HBB-55 + ACCAUGGUGUCUGUUUG 17 408 HBB-28 − ACCUCAAACAGACACCA 17 409 HBB-20 + ACCUUGAUACCAACCUGCCC 20 410 HBB-45 − AGGAGACCAAUAGAAAC 17 411 HBB-54 + AGGAGUCAGAUGCACCA 17 412 HBB-3 − AGUCUGCCGUUACUGCCCUG 20 413 HBB-38 − AGUUGGUGGUGAGGCCC 17 414 HBB-23 + CACGUUCACCUUGCCCCACA 20 415 HBB-2 − CAUGGUGCAUCUGACUCCUG 20 416 HBB-22 + CCACGUUCACCUUGCCCCAC 20 417 HBB-15 − CCCUGGGCAGGUUGGUAUCA 20 418 HBB-7 − CCUGUGGGGCAAGGUGAACG 20 419 HBB-21 + CCUUGAUACCAACCUGCCCA 20 420 HBB-10 − CGUGGAUGAAGUUGGUGGUG 20 421 HBB-6 − CGUUACUGCCCUGUGGGGCA 20 422 HBB-50 + CGUUCACCUUGCCCCAC 17 423 HBB-26 + CUCAGGAGUCAGAUGCACCA 20 424 HBB-30 − CUGCCGUUACUGCCCUG 17 425 HBB-24 + CUUGCCCCACAGGGCAGUAA 20 426 HBB-19 − UAAGGAGACCAAUAGAAACU 20 427 HBB-33 − UACUGCCCUGUGGGGCA 17 428 HBB-43 − UAUCAAGGUUACAAGAC 17 429 HBB-5 − UCUGCCGUUACUGCCCUGUG 20 430 HBB-11 − UGAAGUUGGUGGUGAGGCCC 20 431 HBB-41 − UGAGGCCCUGGGCAGGU 17 432 HBB-49 + UGAUACCAACCUGCCCA 17 433 HBB-27 + UGCACCAUGGUGUCUGUUUG 20 434 HBB-31 − UGCCGUUACUGCCCUGU 17 435 HBB-42 − UGGGCAGGUUGGUAUCA 17 436 HBB-16 − UGGUAUCAAGGUUACAAGAC 20 437 HBB-14 − UGGUGAGGCCCUGGGCAGGU 20 438 HBB-18 − UUAAGGAGACCAAUAGAAAC 20 439 HBB-48 + UUGAUACCAACCUGCCC 17 440 HBB-13 − UUGGUGGUGAGGCCCUGGGC 20 441

Table 1D provides exemplary targeting domains for the E6V target site in the HBB gene selected based on close proximity to mutation. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that gives double stranded cleavage. Any of the targeting domains in the table can be used with S. aureus single-stranded break nucleases (nickases). In an embodiment, dual targeting is used to create two nicks. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position.

TABLE ID Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO HBB-56 − CACCAUGGUGCAUCUGACUC 20 442 HBB-57 − CCAUGGUGCAUCUGACUCCU 20 443 HBB-58 − CAUGGUGCAUCUGACUCCUG 20 444 HBB-59 − UGGUGCAUCUGACUCCUGAG 20 445 HBB-60 − AAGUCUGCCGUUACUGCCCU 20 446 HBB-61 − AGUCUGCCGUUACUGCCCUG 20 447 HBB-62 − UUACUGCCCUGUGGGGCAAG 20 448 HBB-63 − CCCUGUGGGGCAAGGUGAAC 20 449 HBB-64 − GUGGGGCAAGGUGAACGUGG 20 450 HBB-65 − GAACGUGGAUGAAGUUGGUG 20 451 HBB-66 − AUGAAGUUGGUGGUGAGGCC 20 452 HBB-67 − CAAGGUUACAAGACAGGUUU 20 453 HBB-68 − AAGGUUACAAGACAGGUUUA 20 454 HBB-69 − GACAGGUUUAAGGAGACCAA 20 455 HBB-70 − UUUAAGGAGACCAAUAGAAA 20 456 HBB-71 − CAUGGUGCAUCUGACUC 20 457 HBB-72 − UGGUGCAUCUGACUCCU 17 458 HBB-73 − GGUGCAUCUGACUCCUG 17 459 HBB-74 − UGCAUCUGACUCCUGAG 17 460 HBB-75 − UCUGCCGUUACUGCCCU 17 461 HBB-76 − CUGCCGUUACUGCCCUG 17 462 HBB-77 − CUGCCCUGUGGGGCAAG 17 463 HBB-78 − UGUGGGGCAAGGUGAAC 17 464 HBB-79 − GGGCAAGGUGAACGUGG 17 465 HBB-80 − CGUGGAUGAAGUUGGUG 17 466 HBB-81 − AAGUUGGUGGUGAGGCC 17 467 HBB-82 − GGUUACAAGACAGGUUU 17 468 HBB-83 − GUUACAAGACAGGUUUA 17 469 HBB-84 − AGGUUUAAGGAGACCAA 17 470 HBB-85 − AAGGAGACCAAUAGAAA 17 471 HBB-86 + GCUAGUGAACACAGUUGUGU 20 472 HBB-87 + GUGUCUGUUUGAGGUUGCUA 20 473 HBB-88 + AGAUGCACCAUGGUGUCUGU 20 474 HBB-89 + GUAACGGCAGACUUCUCCUC 20 475 HBB-90 + AGUAACGGCAGACUUCUCCU 20 476 HBB-91 + UCCACGUUCACCUUGCCCCA 20 477 HBB-92 + AACCUUGAUACCAACCUGCC 20 478 HBB-93 + AGUGAACACAGUUGUGU 17 479 HBB-94 + UCUGUUUGAGGUUGCUA 17 480 HBB-95 + UGCACCAUGGUGUCUGU 17 481 HBB-96 + ACGGCAGACUUCUCCUC 17 482 HBB-97 + AACGGCAGACUUCUCCU 17 483 HBB-98 + ACGUUCACCUUGCCCCA 17 484 HBB-99 + CUUGAUACCAACCUGCC 17 485

Table 2A provides exemplary targeting domains for knocking out the BCL11A gene selected according to first tier parameters, and are selected based on close proximity to start of the coding sequence and orthogonality in the human genome. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that gives double stranded cleavage. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 single-stranded break nucleases (nickases). In an embodiment, dual targeting is used to create two nicks. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position. In an embodiment, two 20-mer guide RNAs are used to target two S. pyogenes Cas9 nucleases or two S. pyogenes Cas9 nickases, e.g., BCL11A-31 and BCL11A-40, BCL11A-30 and BCL11A-42, or BCL11A-24 and BCL11A-53 are used. In an embodiment, two 17-mer RNAs are used to target two Cas9 nucleases or two Cas9 nickases, e.g., BCL11A-79 and BCL11A-90, BCL11A-77 and BCL11A-92, or BCL11A-71 and BCL11A-103 are used.

TABLE 2A 1st Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-32 - UGGCAUCCAGGUCACGCCAG 20 486 BCL11A-40 + GAUGCUUUUUUCAUCUCGAU 20 487 BCL11A-30 - GCAUCCAAUCCCGUGGAGGU 20 488 BCL11A-42 + UUUUCAUCUCGAUUGGUGAA 20 489 BCL11A-24 - CCAGAUGAACUUCCCAUUGG 20 490 BCL11A-53 + AGGAGGUCAUGAUCCCCUUC 20 491 BCL11A-79 - CAUCCAGGUCACGCCAG 17 492 BCL11A-90 + GCUUUUUUCAUCUCGAU 17 493 BCL11A-77 - UCCAAUCCCGUGGAGGU 17 494 BCL11A-92 + UCAUCUCGAUUGGUGAA 17 495 BCL11A-71 - GAUGAACUUCCCAUUGG 17 496 BCL11A-103 + AGGUCAUGAUCCCCUUC 17 497

Table 2B provides exemplary targeting domains for knocking out the BCL11A gene selected according to the second tier parameters and are selected based on close proximity to start of the coding sequence and presence of a 5′ G. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that gives double stranded cleavage. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 single-stranded break nucleases (nickases). In an embodiment, dual targeting is used to create two nicks. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position.

TABLE 2B 2nd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-28 - GAAAAAAGCAUCCAAUCCCG 20 498 BCL11A-15 - GAACCAGACCACGGCCCGUU 20 499 BCL11A-37 + GACCUGGAUGCCAACCUCCA 20 500 BCL11A-120 + GAGCUCCAUGUGCAGAACGA 20 501 BCL11A-106 + GAGCUCCCAACGGGCCG 17 502 BCL11A-112 - GAGCUCUAAUCCCCACGCCU 20 503 BCL11A-113 - GAGUGCAGAAUAUGCCCCGC 20 504 BCL11A-35 + GAUAAACAAUCGUCAUCCUC 20 505 BCL11A-19 - GAUCAUGACCUCCUCACCUG 20 506 BCL11A-60 - GAUGAUGAACCAGACCA 17 507 BCL11A-39 + GAUGCCAACCUCCACGGGAU 20 508 BCL11A-133 + GCACUCAUCCCAGGCGU 17 509 BCL11A-130 - GCAGAAUAUGCCCCGCA 17 510 BCL11A-115 + GCAUAUUCUGCACUCAUCCC 20 511 BCL11A-89 + GCCAACCUCCACGGGAU 17 512 BCL11A-23 - GCCAGAUGAACUUCCCAUUG 20 513 BCL11A-17 - GCCCGUUGGGAGCUCCAGAA 20 514 BCL11A-83 + GCUAUGUGUUCCUGUUU 17 515 BCL11A-135 + GCUCCAUGUGCAGAACG 17 516 BCL11A-57 + GCUCCCAACGGGCCGUGGUC 20 517 BCL11A-127 - GCUCUAAUCCCCACGCC 17 518 BCL11A-6 + GCUGGGGUUUGCCUUGCUUG 20 519 BCL11A-111 - GGAGCUCUAAUCCCCACGCC 20 520 BCL11A-101 + GGCACUGCCCACAGGUG 17 521 BCL11A-52 + GGCACUGCCCACAGGUGAGG 20 522 BCL11A-16 - GGCCCGUUGGGAGCUCCAGA 20 523 BCL11A-12 + GGGGUUUGCCUUGCUUG 17 524 BCL11A-109 + GUAAGAAUGGCUUCAAG 17 525 BCL11A-123 + GUGCAGAACGAGGGGAGGAG 20 526 BCL11A-21 - GUGCCAGAUGAACUUCCCAU 20 527 BCL11A-50 + GUUCAUCUGGCACUGCCCAC 20 528 BCL11A-65 - GUUGGGAGCUCCAGAAG 17 529

Table 2C provides exemplary targeting domains for knocking out the BCL11A gene selected according to the third tier parameters and are selected based on close proximity to start of the coding sequence. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that gives double stranded cleavage. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 single-stranded break nucleases (nickases). In an embodiment, dual targeting is used to create two nicks. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position.

TABLE 2C 3rd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-75 - AAAAGCAUCCAAUCCCG 17 530 BCL11A-29 - AAAAGCAUCCAAUCCCGUGG 20 531 BCL11A-47 + AAAAUAAGAAUGUCCCCCAA 20 532 BCL11A-85 + AAACAAUCGUCAUCCUC 17 533 BCL11A-73 - AAACGGAAACAAUGCAA 17 534 BCL11A-125 - AAACUUCUGCACUGGAG 17 535 BCL11A-48 + AAAUAAGAAUGUCCCCCAAU 20 536 BCL11A-1 - AACCCCAGCACUUAAGCAAA 20 537 BCL11A-13 - ACAGAUGAUGAACCAGACCA 20 538 BCL11A-61 - ACCAGACCACGGCCCGU 17 539 BCL11A-2 - ACCCCAGCACUUAAGCAAAC 20 540 BCL11A-38 + ACCUGGAUGCCAACCUCCAC 20 541 BCL11A-102 + ACUGCCCACAGGUGAGG 17 542 BCL11A-119 + AGAGCUCCAUGUGCAGAACG 20 543 BCL11A-70 - AGAUGAACUUCCCAUUG 17 544 BCL11A-76 - AGCAUCCAAUCCCGUGG 17 545 BCL11A-121 + AGCUCCAUGUGCAGAACGAG 20 546 BCL11A-81 - AGGAAUUUGCCCCAAAC 17 547 BCL11A-114 - AGUGCAGAAUAUGCCCCGCA 20 548 BCL11A-97 + AUAAGAAUGUCCCCCAA 17 549 BCL11A-20 - AUCAUGACCUCCUCACCUGU 20 550 BCL11A-44 + AUCUCGAUUGGUGAAGGGGA 20 551 BCL11A-67 - AUGACCUCCUCACCUGU 17 552 BCL11A-138 + AUGUGCAGAACGAGGGG 17 553 BCL11A-3 + AUUCCCGUUUGCUUAAGUGC 20 554 BCL11A-95 + AUUGGUGAAGGGGAAGG 17 555 BCL11A-26 - CACAAACGGAAACAAUGCAA 20 556 BCL11A-134 + CACUCAUCCCAGGCGUG 17 557 BCL11A-139 + CAGAACGAGGGGAGGAG 17 558 BCL11A-69 - CAGAUGAACUUCCCAUU 17 559 BCL11A-96 + CAGCUUUUUCUAAGCAG 17 560 BCL11A-86 + CAUCCUCUGGCGUGACC 17 561 BCL11A-93 + CAUCUCGAUUGGUGAAG 17 562 BCL11A-100 + CAUCUGGCACUGCCCAC 17 563 BCL11A-66 - CAUGACCUCCUCACCUG 17 564 BCL11A-99 + CCAAUGGGAAGUUCAUC 17 565 BCL11A-46 + CCACAGCUUUUUCUAAGCAG 20 566 BCL11A-62 - CCAGACCACGGCCCGUU 17 567 BCL11A-68 - CCAGAUGAACUUCCCAU 17 568 BCL11A-8 - CCAGCACUUAAGCAAAC 17 569 BCL11A-107 + CCCAACGGGCCGUGGUC 17 570 BCL11A-7 - CCCAGCACUUAAGCAAA 17 571 BCL11A-49 + CCCCCAAUGGGAAGUUCAUC 20 572 BCL11A-55 + CCCCUUCUGGAGCUCCCAAC 20 573 BCL11A-18 - CCCGUUGGGAGCUCCAGAAG 20 574 BCL11A-9 + CCCGUUUGCUUAAGUGC 17 575 BCL11A-63 - CCGUUGGGAGCUCCAGA 17 576 BCL11A-10 + CCGUUUGCUUAAGUGCU 17 577 BCL11A-27 - CCUCUGCUUAGAAAAAGCUG 20 578 BCL11A-104 + CCUUCUGGAGCUCCCAA 17 579 BCL11A-36 + CGUCAUCCUCUGGCGUGACC 20 580 BCL11A-78 - CGUGGAGGUUGGCAUCC 17 581 BCL11A-64 - CGUUGGGAGCUCCAGAA 17 582 BCL11A-11 + CGUUUGCUUAAGUGCUG 17 583 BCL11A-84 + CUAUGUGUUCCUGUUUG 17 584 BCL11A-136 + CUCCAUGUGCAGAACGA 17 585 BCL11A-128 - CUCUAAUCCCCACGCCU 17 586 BCL11A-118 + CUGCACUCAUCCCAGGCGUG 20 587 BCL11A-74 - CUGCUUAGAAAAAGCUG 17 588 BCL11A-56 + CUGGAGCUCCCAACGGGCCG 20 589 BCL11A-87 + CUGGAUGCCAACCUCCA 17 590 BCL11A-105 + CUUCUGGAGCUCCCAAC 17 591 BCL11A-124 - UAAACUUCUGCACUGGA 17 592 BCL11A-98 + UAAGAAUGUCCCCCAAU 17 593 BCL11A-34 - UAGAGGAAUUUGCCCCAAAC 20 594 BCL11A-131 + UAUUCUGCACUCAUCCC 17 595 BCL11A-137 + UCCAUGUGCAGAACGAG 17 596 BCL11A-122 + UCCAUGUGCAGAACGAGGGG 20 597 BCL11A-126 - UCCCCUCGUUCUGCACA 17 598 BCL11A-54 + UCCCCUUCUGGAGCUCCCAA 20 599 BCL11A-31 - UCCCGUGGAGGUUGGCAUCC 20 600 BCL11A-5 + UCCCGUUUGCUUAAGUGCUG 20 601 BCL11A-110 - UCCUCCCCUCGUUCUGCACA 20 602 BCL11A-94 + UCGAUUGGUGAAGGGGA 17 603 BCL11A-45 + UCGAUUGGUGAAGGGGAAGG 20 604 BCL11A-117 + UCUGCACUCAUCCCAGGCGU 20 605 BCL11A-51 + UCUGGCACUGCCCACAGGUG 20 606 BCL11A-59 + UCUGUAAGAAUGGCUUCAAG 20 607 BCL11A-14 - UGAACCAGACCACGGCCCGU 20 608 BCL11A-132 + UGCACUCAUCCCAGGCG 17 609 BCL11A-129 - UGCAGAAUAUGCCCCGC 17 610 BCL11A-22 - UGCCAGAUGAACUUCCCAUU 20 611 BCL11A-82 + UGCUAUGUGUUCCUGUU 17 612 BCL11A-88 + UGGAUGCCAACCUCCAC 17 613 BCL11A-58 + UGGUUCAUCAUCUGUAAGAA 20 614 BCL11A-33 - UGUUUAUCAACGUCAUCUAG 20 615 BCL11A-80 - UUAUCAACGUCAUCUAG 17 616 BCL11A-25 - UUAUUUUUAUCGAGCACAAA 20 617 BCL11A-108 + UUCAUCAUCUGUAAGAA 17 618 BCL11A-91 + UUCAUCUCGAUUGGUGA 17 619 BCL11A-4 + UUCCCGUUUGCUUAAGUGCU 20 620 BCL11A-116 + UUCUGCACUCAUCCCAGGCG 20 621 BCL11A-43 + UUUCAUCUCGAUUGGUGAAG 20 622 BCL11A-72 - UUUUUAUCGAGCACAAA 17 623 BCL11A-41 + UUUUUCAUCUCGAUUGGUGA 20 624

Table 2D) provides exemplary targeting domains for knocking out the BCL11A gene selected according to the fourth tier parameters and are selected based on presence in the coding sequence. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that gives double stranded cleavage. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 single-stranded break nucleases (nickases). In an embodiment, dual targeting is used to create two nicks. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position.

TABLE 2D 4th Tier DNA Target Site SEQ ID gRNA Name Strand Targeting domain Length NO BCL11A-140 - AACAGCCAUUCACCAGUGCA 20 625 BCL11A-141 - CAACACGCACAGAACACUCA 20 626 BCL11A-142 - AUCUACUUAGAAAGCGAACA 20 627 BCL11A-143 - ACGGAAGUCCCCUGACCCCG 20 628 BCL11A-144 - CGGAAGUCCCCUGACCCCGC 20 629 BCL11A-145 - AGUCCCCUGACCCCGCGGGU 20 630 BCL11A-146 - CCGCGGGUUGGUAUCCCUUC 20 631 BCL11A-147 - GUUGGUAUCCCUUCAGGACU 20 632 BCL11A-148 - CCUUCCCAGCCACCUCUCCA 20 633 BCL11A-149 - CUUCCCAGCCACCUCUCCAU 20 634 BCL11A-150 - UUUAACCUGCUAAGAAUACC 20 635 BCL11A-151 - ACCAGGAUCAGUAUCGAGAG 20 636 BCL11A-152 - UCAGUAUCGAGAGAGGCUUC 20 637 BCL11A-153 - AUCGAGAGAGGCUUCCGGCC 20 638 BCL11A-154 - GAGGCUUCCGGCCUGGCAGA 20 639 BCL11A-155 - AGGCUUCCGGCCUGGCAGAA 20 640 BCL11A-156 - UCCACCACCGAGACAUCACU 20 641 BCL11A-157 - CCCCCACCGCAUAGAGCGCC 20 642 BCL11A-158 - CCCCACCGCAUAGAGCGCCU 20 643 BCL11A-159 - CCCACCGCAUAGAGCGCCUG 20 644 BCL11A-160 - CCACCGCAUAGAGCGCCUGG 20 645 BCL11A-161 - CCGCAUAGAGCGCCUGGGGG 20 646 BCL11A-162 - GCGCCUGGGGGCGGAAGAGA 20 647 BCL11A-163 - GGGGGCGGAAGAGAUGGCCC 20 648 BCL11A-164 - AUCACCCGAGUGCCUUUGAC 20 649 BCL11A-165 - UCACCCGAGUGCCUUUGACA 20 650 BCL11A-166 - GUGCCUUUGACAGGGUGCUG 20 651 BCL11A-167 - GGUGCUGCGGUUGAAUCCAA 20 652 BCL11A-168 - GCGGUUGAAUCCAAUGGCUA 20 653 BCL11A-169 - GGCUAUGGAGCCUCCCGCCA 20 654 BCL11A-170 - CUCCCGCCAUGGAUUUCUCU 20 655 BCL11A-171 - CUCUAGGAGACUUAGAGAGC 20 656 BCL11A-172 - AGGAGACUUAGAGAGCUGGC 20 657 BCL11A-173 - GGAGACUUAGAGAGCUGGCA 20 658 BCL11A-174 - UCUAGCCCACCGCUGUCCCC 20 659 BCL11A-175 - GCCCACCGCUGUCCCCAGGC 20 660 BCL11A-176 - GCCGGCCCAGCCCUAUGCAA 20 661 BCL11A-177 - UUACUGCAACCAUUCCAGCC 20 662 BCL11A-178 - AGGUAGCAAGCCGCCCUUCC 20 663 BCL11A-179 - CCCUCCUCCCUCCCAGCCCC 20 664 BCL11A-180 - UCCAAGUCAUGCGAGUUCUG 20 665 BCL11A-181 - GUUCAAAUUUCAGAGCAACC 20 666 BCL11A-182 - CAAAUUUCAGAGCAACCUGG 20 667 BCL11A-183 - AGAGCAACCUGGUGGUGCAC 20 668 BCL11A-184 - GGUGCACCGGCGCAGCCACA 20 669 BCL11A-185 - GUGCACCGGCGCAGCCACAC 20 670 BCL11A-186 - GUGCGACCACGCGUGCACCC 20 671 BCL11A-187 - GCACAAAUCGUCCCCCAUGA 20 672 BCL11A-188 - AUGACGGUCAAGUCCGACGA 20 673 BCL11A-189 - UCUCUCCACCGCCAGCUCCC 20 674 BCL11A-190 - ACCGCCAGCUCCCCGGAACC 20 675 BCL11A-191 - GGAACCCGGCACCAGCGACU 20 676 BCL11A-192 - ACCCGGCACCAGCGACUUGG 20 677 BCL11A-193 - CCCGGCACCAGCGACUUGGU 20 678 BCL11A-194 - CAGCAGCGCGCUCAAGUCCG 20 679 BCL11A-195 - CAGCGCGCUCAAGUCCGUGG 20 680 BCL11A-196 - GAACGACCCCAACCUGAUCC 20 681 BCL11A-197 - CCCAACCUGAUCCCGGAGAA 20 682 BCL11A-198 - CCAACCUGAUCCCGGAGAAC 20 683 BCL11A-199 - CAACCUGAUCCCGGAGAACG 20 684 BCL11A-200 - GAUCCCGGAGAACGGGGACG 20 685 BCL11A-201 - CCCGGAGAACGGGGACGAGG 20 686 BCL11A-202 - GAACGGGGACGAGGAGGAAG 20 687 BCL11A-203 - CGGGGACGAGGAGGAAGAGG 20 688 BCL11A-204 - GGAGGAAGAGGAGGACGACG 20 689 BCL11A-205 - AGAGGAGGACGACGAGGAAG 20 690 BCL11A-206 - CGACGAGGAAGAGGAAGAAG 20 691 BCL11A-207 - CGAGGAAGAGGAAGAAGAGG 20 692 BCL11A-208 - AGAGGAAGAAGAGGAGGAAG 20 693 BCL11A-209 - GGAAGAAGAGGAGGAAGAGG 20 694 BCL11A-210 - AGAAGAGGAGGAAGAGGAGG 20 695 BCL11A-211 - AGAGGAGGAAGAGGAGGAGG 20 696 BCL11A-212 + UCCUCCUCGUCCCCGUUCUC 20 697 BCL11A-213 + CCUCCUCGUCCCCGUUCUCC 20 698 BCL11A-214 + CGUCCCCGUUCUCCGGGAUC 20 699 BCL11A-215 + CCCGUUCUCCGGGAUCAGGU 20 700 BCL11A-216 + CCGUUCUCCGGGAUCAGGUU 20 701 BCL11A-217 + CGUUCUCCGGGAUCAGGUUG 20 702 BCL11A-218 + GUCGUUCUCGCUCUUGAACU 20 703 BCL11A-219 + GCUCUUGAACUUGGCCACCA 20 704 BCL11A-220 + CACGGACUUGAGCGCGCUGC 20 705 BCL11A-221 + GGCGCUGCCCACCAAGUCGC 20 706 BCL11A-222 + GCCCACCAAGUCGCUGGUGC 20 707 BCL11A-223 + CCCACCAAGUCGCUGGUGCC 20 708 BCL11A-224 + AAGUCGCUGGUGCCGGGUUC 20 709 BCL11A-225 + AGUCGCUGGUGCCGGGUUCC 20 710 BCL11A-226 + GUCGCUGGUGCCGGGUUCCG 20 711 BCL11A-227 + GGUGCCGGGUUCCGGGGAGC 20 712 BCL11A-228 + GCCGGGUUCCGGGGAGCUGG 20 713 BCL11A-229 + GGGUUCCGGGGAGCUGGCGG 20 714 BCL11A-230 + GGCGGUGGAGAGACCGUCGU 20 715 BCL11A-231 + GUCGUCGGACUUGACCGUCA 20 716 BCL11A-232 + UCGUCGGACUUGACCGUCAU 20 717 BCL11A-233 + CGUCGGACUUGACCGUCAUG 20 718 BCL11A-234 + GUCGGACUUGACCGUCAUGG 20 719 BCL11A-235 + UGUGCAUGUGCGUCUUCAUG 20 720 BCL11A-236 + CAUGUGGCGCUUCAGCUUGC 20 721 BCL11A-237 + GGCGCUUCAGCUUGCUGGCC 20 722 BCL11A-238 + GCGCUUCAGCUUGCUGGCCU 20 723 BCL11A-239 + UGCUGGCCUGGGUGCACGCG 20 724 BCL11A-240 + GGGUGCACGCGUGGUCGCAC 20 725 BCL11A-241 + GUCGCACAGGUUGCACUUGU 20 726 BCL11A-242 + UCGCACAGGUUGCACUUGUA 20 727 BCL11A-243 + UGUAGGGCUUCUCGCCCGUG 20 728 BCL11A-244 + UCUCGCCCGUGUGGCUGCGC 20 729 BCL11A-245 + GGCUGCGCCGGUGCACCACC 20 730 BCL11A-246 + GCCGCAGAACUCGCAUGACU 20 731 BCL11A-247 + UCGCAUGACUUGGACUUGAC 20 732 BCL11A-248 + CGCAUGACUUGGACUUGACC 20 733 BCL11A-249 + GCAUGACUUGGACUUGACCG 20 734 BCL11A-250 + CAUGACUUGGACUUGACCGG 20 735 BCL11A-251 + ACUUGGACUUGACCGGGGGC 20 736 BCL11A-252 + CUUGGACUUGACCGGGGGCU 20 737 BCL11A-253 + GGACUUGACCGGGGGCUGGG 20 738 BCL11A-254 + GACUUGACCGGGGGCUGGGA 20 739 BCL11A-255 + UUGACCGGGGGCUGGGAGGG 20 740 BCL11A-256 + ACCGGGGGCUGGGAGGGAGG 20 741 BCL11A-257 + CCGGGGGCUGGGAGGGAGGA 20 742 BCL11A-258 + CGGGGGCUGGGAGGGAGGAG 20 743 BCL11A-259 + GGGCUGGGAGGGAGGAGGGG 20 744 BCL11A-260 + GGAGGAGGGGCGGAUUGCAG 20 745 BCL11A-261 + GGAGGGGCGGAUUGCAGAGG 20 746 BCL11A-262 + GAGGGGCGGAUUGCAGAGGA 20 747 BCL11A-263 + GGGCGGAUUGCAGAGGAGGG 20 748 BCL11A-264 + GGCGGAUUGCAGAGGAGGGA 20 749 BCL11A-265 + GCGGAUUGCAGAGGAGGGAG 20 750 BCL11A-266 + CGGAUUGCAGAGGAGGGAGG 20 751 BCL11A-267 + GGAUUGCAGAGGAGGGAGGG 20 752 BCL11A-268 + GAUUGCAGAGGAGGGAGGGG 20 753 BCL11A-269 + GAGGGAGGGGGGGCGUCGCC 20 754 BCL11A-270 + GAGGGGGGGCGUCGCCAGGA 20 755 BCL11A-271 + AGGGGGGGCGUCGCCAGGAA 20 756 BCL11A-272 + GGGGGCGUCGCCAGGAAGGG 20 757 BCL11A-273 + AGGAAGGGCGGCUUGCUACC 20 758 BCL11A-274 + AGGGCGGCUUGCUACCUGGC 20 759 BCL11A-275 + GGCUUGCUACCUGGCUGGAA 20 760 BCL11A-276 + GGUUGCAGUAACCUUUGCAU 20 761 BCL11A-277 + GUUGCAGUAACCUUUGCAUA 20 762 BCL11A-278 + CAGUAACCUUUGCAUAGGGC 20 763 BCL11A-279 + AGUAACCUUUGCAUAGGGCU 20 764 BCL11A-280 + ACCUUUGCAUAGGGCUGGGC 20 765 BCL11A-281 + UGCAUAGGGCUGGGCCGGCC 20 766 BCL11A-282 + GCAUAGGGCUGGGCCGGCCU 20 767 BCL11A-283 + CAUAGGGCUGGGCCGGCCUG 20 768 BCL11A-284 + CUGGGCCGGCCUGGGGACAG 20 769 BCL11A-285 + GGCCGGCCUGGGGACAGCGG 20 770 BCL11A-286 + GCCGGCCUGGGGACAGCGGU 20 771 BCL11A-287 + AAGUCUCCUAGAGAAAUCCA 20 772 BCL11A-288 + UCUCCUAGAGAAAUCCAUGG 20 773 BCL11A-289 + CUCCUAGAGAAAUCCAUGGC 20 774 BCL11A-290 + CUAGAGAAAUCCAUGGCGGG 20 775 BCL11A-291 + GCGGGAGGCUCCAUAGCCAU 20 776 BCL11A-292 + CAACCGCAGCACCCUGUCAA 20 777 BCL11A-293 + AGCACCCUGUCAAAGGCACU 20 778 BCL11A-294 + GCACCCUGUCAAAGGCACUC 20 779 BCL11A-295 + UGUCAAAGGCACUCGGGUGA 20 780 BCL11A-296 + GUCAAAGGCACUCGGGUGAU 20 781 BCL11A-297 + AAAGGCACUCGGGUGAUGGG 20 782 BCL11A-298 + CACUCGGGUGAUGGGUGGCC 20 783 BCL11A-299 + ACUCGGGUGAUGGGUGGCCA 20 784 BCL11A-300 + GGGCCAUCUCUUCCGCCCCC 20 785 BCL11A-301 + CCGCCCCCAGGCGCUCUAUG 20 786 BCL11A-302 + CCCCCAGGCGCUCUAUGCGG 20 787 BCL11A-303 + CCCCAGGCGCUCUAUGCGGU 20 788 BCL11A-304 + CCCAGGCGCUCUAUGCGGUG 20 789 BCL11A-305 + CCAGGCGCUCUAUGCGGUGG 20 790 BCL11A-306 + UGGGGGUCCAAGUGAUGUCU 20 791 BCL11A-307 + GGGUCCAAGUGAUGUCUCGG 20 792 BCL11A-308 + UCCAAGUGAUGUCUCGGUGG 20 793 BCL11A-309 + GUCUCGGUGGUGGACUAAAC 20 794 BCL11A-310 + UCUCGGUGGUGGACUAAACA 20 795 BCL11A-311 + CUCGGUGGUGGACUAAACAG 20 796 BCL11A-312 + UCGGUGGUGGACUAAACAGG 20 797 BCL11A-313 + CGGUGGUGGACUAAACAGGG 20 798 BCL11A-314 + GGUGGUGGACUAAACAGGGG 20 799 BCL11A-315 + UGGACUAAACAGGGGGGGAG 20 800 BCL11A-316 + GGACUAAACAGGGGGGGAGU 20 801 BCL11A-317 + CUAAACAGGGGGGGAGUGGG 20 802 BCL11A-318 + GUGGAAAGCGCCCUUCUGCC 20 803 BCL11A-319 + AAAGCGCCCUUCUGCCAGGC 20 804 BCL11A-320 + GCCUCUCUCGAUACUGAUCC 20 805 BCL11A-321 + CUGAUCCUGGUAUUCUUAGC 20 806 BCL11A-322 + UGGUAUUCUUAGCAGGUUAA 20 807 BCL11A-323 + GGUAUUCUUAGCAGGUUAAA 20 808 BCL11A-324 + GUAUUCUUAGCAGGUUAAAG 20 809 BCL11A-325 + UGUCUGCAAUAUGAAUCCCA 20 810 BCL11A-326 + GCAAUAUGAAUCCCAUGGAG 20 811 BCL11A-327 + AUAUGAAUCCCAUGGAGAGG 20 812 BCL11A-328 + GAAUCCCAUGGAGAGGUGGC 20 813 BCL11A-329 + AAUCCCAUGGAGAGGUGGCU 20 814 BCL11A-330 + CCAUGGAGAGGUGGCUGGGA 20 815 BCL11A-331 + CAUUCUGCACCUAGUCCUGA 20 816 BCL11A-332 + AUUCUGCACCUAGUCCUGAA 20 817 BCL11A-333 + CCUGAAGGGAUACCAACCCG 20 818 BCL11A-334 + CUGAAGGGAUACCAACCCGC 20 819 BCL11A-335 + UGAAGGGAUACCAACCCGCG 20 820 BCL11A-336 + GGAUACCAACCCGCGGGGUC 20 821 BCL11A-337 + GAUACCAACCCGCGGGGUCA 20 822 BCL11A-338 + AUACCAACCCGCGGGGUCAG 20 823 BCL11A-339 + UUGCAAGAGAAACCAUGCAC 20 824 BCL11A-340 + AGAAACCAUGCACUGGUGAA 20 825 BCL11A-341 + AGUUGUACAUGUGUAGCUGC 20 826 BCL11A-342 + GUUGUACAUGUGUAGCUGCU 20 827 BCL11A-343 - AGCCAUUCACCAGUGCA 17 828 BCL11A-344 - CACGCACAGAACACUCA 17 829 BCL11A-345 - UACUUAGAAAGCGAACA 17 830 BCL11A-346 - GAAGUCCCCUGACCCCG 17 831 BCL11A-347 - AAGUCCCCUGACCCCGC 17 832 BCL11A-348 - CCCCUGACCCCGCGGGU 17 833 BCL11A-349 - CGGGUUGGUAUCCCUUC 17 834 BCL11A-350 - GGUAUCCCUUCAGGACU 17 835 BCL11A-351 - UCCCAGCCACCUCUCCA 17 836 BCL11A-352 - CCCAGCCACCUCUCCAU 17 837 BCL11A-353 - AACCUGCUAAGAAUACC 17 838 BCL11A-354 - AGGAUCAGUAUCGAGAG 17 839 BCL11A-355 - GUAUCGAGAGAGGCUUC 17 840 BCL11A-356 - GAGAGAGGCUUCCGGCC 17 841 BCL11A-357 - GCUUCCGGCCUGGCAGA 17 842 BCL11A-358 - CUUCCGGCCUGGCAGAA 17 843 BCL11A-359 - ACCACCGAGACAUCACU 17 844 BCL11A-360 - CCACCGCAUAGAGCGCC 17 845 BCL11A-361 - CACCGCAUAGAGCGCCU 17 846 BCL11A-362 - ACCGCAUAGAGCGCCUG 17 847 BCL11A-363 - CCGCAUAGAGCGCCUGG 17 848 BCL11A-364 - CAUAGAGCGCCUGGGGG 17 849 BCL11A-365 - CCUGGGGGCGGAAGAGA 17 850 BCL11A-366 - GGCGGAAGAGAUGGCCC 17 851 BCL11A-367 - ACCCGAGUGCCUUUGAC 17 852 BCL11A-368 - CCCGAGUGCCUUUGACA 17 853 BCL11A-369 - CCUUUGACAGGGUGCUG 17 854 BCL11A-370 - GCUGCGGUUGAAUCCAA 17 855 BCL11A-371 - GUUGAAUCCAAUGGCUA 17 856 BCL11A-372 - UAUGGAGCCUCCCGCCA 17 857 BCL11A-373 - CCGCCAUGGAUUUCUCU 17 858 BCL11A-374 - UAGGAGACUUAGAGAGC 17 859 BCL11A-375 - AGACUUAGAGAGCUGGC 17 860 BCL11A-376 - GACUUAGAGAGCUGGCA 17 861 BCL11A-377 - AGCCCACCGCUGUCCCC 17 862 BCL11A-378 - CACCGCUGUCCCCAGGC 17 863 BCL11A-379 - GGCCCAGCCCUAUGCAA 17 864 BCL11A-380 - CUGCAACCAUUCCAGCC 17 865 BCL11A-381 - UAGCAAGCCGCCCUUCC 17 866 BCL11A-382 - UCCUCCCUCCCAGCCCC 17 867 BCL11A-383 - AAGUCAUGCGAGUUCUG 17 868 BCL11A-384 - CAAAUUUCAGAGCAACC 17 869 BCL11A-385 - AUUUCAGAGCAACCUGG 17 870 BCL11A-386 - GCAACCUGGUGGUGCAC 17 871 BCL11A-387 - GCACCGGCGCAGCCACA 17 872 BCL11A-388 - CACCGGCGCAGCCACAC 17 873 BCL11A-389 - CGACCACGCGUGCACCC 17 874 BCL11A-390 - CAAAUCGUCCCCCAUGA 17 875 BCL11A-391 - ACGGUCAAGUCCGACGA 17 876 BCL11A-392 - CUCCACCGCCAGCUCCC 17 877 BCL11A-393 - GCCAGCUCCCCGGAACC 17 878 BCL11A-394 - ACCCGGCACCAGCGACU 17 879 BCL11A-395 - CGGCACCAGCGACUUGG 17 880 BCL11A-396 - GGCACCAGCGACUUGGU 17 881 BCL11A-397 - CAGCGCGCUCAAGUCCG 17 882 BCL11A-398 - CGCGCUCAAGUCCGUGG 17 883 BCL11A-399 - CGACCCCAACCUGAUCC 17 884 BCL11A-400 - AACCUGAUCCCGGAGAA 17 885 BCL11A-401 - ACCUGAUCCCGGAGAAC 17 886 BCL11A-402 - CCUGAUCCCGGAGAACG 17 887 BCL11A-403 - CCCGGAGAACGGGGACG 17 888 BCL11A-404 - GGAGAACGGGGACGAGG 17 889 BCL11A-405 - CGGGGACGAGGAGGAAG 17 890 BCL11A-406 - GGACGAGGAGGAAGAGG 17 891 BCL11A-407 - GGAAGAGGAGGACGACG 17 892 BCL11A-408 - GGAGGACGACGAGGAAG 17 893 BCL11A-409 - CGAGGAAGAGGAAGAAG 17 894 BCL11A-410 - GGAAGAGGAAGAAGAGG 17 895 BCL11A-411 - GGAAGAAGAGGAGGAAG 17 896 BCL11A-412 - AGAAGAGGAGGAAGAGG 17 897 BCL11A-413 - AGAGGAGGAAGAGGAGG 17 898 BCL11A-414 - GGAGGAAGAGGAGGAGG 17 899 BCL11A-415 + UCCUCGUCCCCGUUCUC 17 900 BCL11A-416 + CCUCGUCCCCGUUCUCC 17 901 BCL11A-417 + CCCCGUUCUCCGGGAUC 17 902 BCL11A-418 + GUUCUCCGGGAUCAGGU 17 903 BCL11A-419 + UUCUCCGGGAUCAGGUU 17 904 BCL11A-420 + UCUCCGGGAUCAGGUUG 17 905 BCL11A-421 + GUUCUCGCUCUUGAACU 17 906 BCL11A-422 + CUUGAACUUGGCCACCA 17 907 BCL11A-423 + GGACUUGAGCGCGCUGC 17 908 BCL11A-424 + GCUGCCCACCAAGUCGC 17 909 BCL11A-425 + CACCAAGUCGCUGGUGC 17 910 BCL11A-426 + ACCAAGUCGCUGGUGCC 17 911 BCL11A-427 + UCGCUGGUGCCGGGUUC 17 912 BCL11A-428 + CGCUGGUGCCGGGUUCC 17 913 BCL11A-429 + GCUGGUGCCGGGUUCCG 17 914 BCL11A-430 + GCCGGGUUCCGGGGAGC 17 915 BCL11A-431 + GGGUUCCGGGGAGCUGG 17 916 BCL11A-432 + UUCCGGGGAGCUGGCGG 17 917 BCL11A-433 + GGUGGAGAGACCGUCGU 17 918 BCL11A-434 + GUCGGACUUGACCGUCA 17 919 BCL11A-435 + UCGGACUUGACCGUCAU 17 920 BCL11A-436 + CGGACUUGACCGUCAUG 17 921 BCL11A-437 + GGACUUGACCGUCAUGG 17 922 BCL11A-438 + GCAUGUGCGUCUUCAUG 17 923 BCL11A-439 + GUGGCGCUUCAGCUUGC 17 924 BCL11A-440 + GCUUCAGCUUGCUGGCC 17 925 BCL11A-441 + CUUCAGCUUGCUGGCCU 17 926 BCL11A-442 + UGGCCUGGGUGCACGCG 17 927 BCL11A-443 + UGCACGCGUGGUCGCAC 17 928 BCL11A-444 + GCACAGGUUGCACUUGU 17 929 BCL11A-445 + CACAGGUUGCACUUGUA 17 930 BCL11A-446 + AGGGCUUCUCGCCCGUG 17 931 BCL11A-447 + CGCCCGUGUGGCUGCGC 17 932 BCL11A-448 + UGCGCCGGUGCACCACC 17 933 BCL11A-449 + GCAGAACUCGCAUGACU 17 934 BCL11A-450 + CAUGACUUGGACUUGAC 17 935 BCL11A-451 + AUGACUUGGACUUGACC 17 936 BCL11A-452 + UGACUUGGACUUGACCG 17 937 BCL11A-453 + GACUUGGACUUGACCGG 17 938 BCL11A-454 + UGGACUUGACCGGGGGC 17 939 BCL11A-455 + GGACUUGACCGGGGGCU 17 940 BCL11A-456 + CUUGACCGGGGGCUGGG 17 941 BCL11A-457 + UUGACCGGGGGCUGGGA 17 942 BCL11A-458 + ACCGGGGGCUGGGAGGG 17 943 BCL11A-459 + GGGGGCUGGGAGGGAGG 17 944 BCL11A-460 + GGGGCUGGGAGGGAGGA 17 945 BCL11A-461 + GGGCUGGGAGGGAGGAG 17 946 BCL11A-462 + CUGGGAGGGAGGAGGGG 17 947 BCL11A-463 + GGAGGGGCGGAUUGCAG 17 948 BCL11A-464 + GGGGCGGAUUGCAGAGG 17 949 BCL11A-465 + GGGCGGAUUGCAGAGGA 17 950 BCL11A-466 + CGGAUUGCAGAGGAGGG 17 951 BCL11A-467 + GGAUUGCAGAGGAGGGA 17 952 BCL11A-468 + GAUUGCAGAGGAGGGAG 17 953 BCL11A-469 + AUUGCAGAGGAGGGAGG 17 954 BCL11A-470 + UUGCAGAGGAGGGAGGG 17 955 BCL11A-471 + UGCAGAGGAGGGAGGGG 17 956 BCL11A-472 + GGAGGGGGGGCGUCGCC 17 957 BCL11A-473 + GGGGGGCGUCGCCAGGA 17 958 BCL11A-474 + GGGGGCGUCGCCAGGAA 17 959 BCL11A-475 + GGCGUCGCCAGGAAGGG 17 960 BCL11A-476 + AAGGGCGGCUUGCUACC 17 961 BCL11A-477 + GCGGCUUGCUACCUGGC 17 962 BCL11A-478 + UUGCUACCUGGCUGGAA 17 963 BCL11A-479 + UGCAGUAACCUUUGCAU 17 964 BCL11A-480 + GCAGUAACCUUUGCAUA 17 965 BCL11A-481 + UAACCUUUGCAUAGGGC 17 966 BCL11A-482 + AACCUUUGCAUAGGGCU 17 967 BCL11A-483 + UUUGCAUAGGGCUGGGC 17 968 BCL11A-484 + AUAGGGCUGGGCCGGCC 17 969 BCL11A-485 + UAGGGCUGGGCCGGCCU 17 970 BCL11A-486 + AGGGCUGGGCCGGCCUG 17 971 BCL11A-487 + GGCCGGCCUGGGGACAG 17 972 BCL11A-488 + CGGCCUGGGGACAGCGG 17 973 BCL11A-489 + GGCCUGGGGACAGCGGU 17 974 BCL11A-490 + UCUCCUAGAGAAAUCCA 17 975 BCL11A-491 + CCUAGAGAAAUCCAUGG 17 976 BCL11A-492 + CUAGAGAAAUCCAUGGC 17 977 BCL11A-493 + GAGAAAUCCAUGGCGGG 17 978 BCL11A-494 + GGAGGCUCCAUAGCCAU 17 979 BCL11A-495 + CCGCAGCACCCUGUCAA 17 980 BCL11A-496 + ACCCUGUCAAAGGCACU 17 981 BCL11A-497 + CCCUGUCAAAGGCACUC 17 982 BCL11A-498 + CAAAGGCACUCGGGUGA 17 983 BCL11A-499 + AAAGGCACUCGGGUGAU 17 984 BCL11A-500 + GGCACUCGGGUGAUGGG 17 985 BCL11A-501 + UCGGGUGAUGGGUGGCC 17 986 BCL11A-502 + CGGGUGAUGGGUGGCCA 17 987 BCL11A-503 + CCAUCUCUUCCGCCCCC 17 988 BCL11A-504 + CCCCCAGGCGCUCUAUG 17 989 BCL11A-505 + CCAGGCGCUCUAUGCGG 17 990 BCL11A-506 + CAGGCGCUCUAUGCGGU 17 991 BCL11A-507 + AGGCGCUCUAUGCGGUG 17 992 BCL11A-508 + GGCGCUCUAUGCGGUGG 17 993 BCL11A-509 + GGGUCCAAGUGAUGUCU 17 994 BCL11A-510 + UCCAAGUGAUGUCUCGG 17 995 BCL11A-511 + AAGUGAUGUCUCGGUGG 17 996 BCL11A-512 + UCGGUGGUGGACUAAAC 17 997 BCL11A-513 + CGGUGGUGGACUAAACA 17 998 BCL11A-514 + GGUGGUGGACUAAACAG 17 999 BCL11A-515 + GUGGUGGACUAAACAGG 17 1000 BCL11A-516 + UGGUGGACUAAACAGGG 17 1001 BCL11A-517 + GGUGGACUAAACAGGGG 17 1002 BCL11A-518 + ACUAAACAGGGGGGGAG 17 1003 BCL11A-519 + CUAAACAGGGGGGGAGU 17 1004 BCL11A-520 + AACAGGGGGGGAGUGGG 17 1005 BCL11A-521 + GAAAGCGCCCUUCUGCC 17 1006 BCL11A-522 + GCGCCCUUCUGCCAGGC 17 1007 BCL11A-523 + UCUCUCGAUACUGAUCC 17 1008 BCL11A-524 + AUCCUGGUAUUCUUAGC 17 1009 BCL11A-525 + UAUUCUUAGCAGGUUAA 17 1010 BCL11A-526 + AUUCUUAGCAGGUUAAA 17 1011 BCL11A-527 + UUCUUAGCAGGUUAAAG 17 1012 BCL11A-528 + CUGCAAUAUGAAUCCCA 17 1013 BCL11A-529 + AUAUGAAUCCCAUGGAG 17 1014 BCL11A-530 + UGAAUCCCAUGGAGAGG 17 1015 BCL11A-531 + UCCCAUGGAGAGGUGGC 17 1016 BCL11A-532 + CCCAUGGAGAGGUGGCU 17 1017 BCL11A-533 + UGGAGAGGUGGCUGGGA 17 1018 BCL11A-534 + UCUGCACCUAGUCCUGA 17 1019 BCL11A-535 + CUGCACCUAGUCCUGAA 17 1020 BCL11A-536 + GAAGGGAUACCAACCCG 17 1021 BCL11A-537 + AAGGGAUACCAACCCGC 17 1022 BCL11A-538 + AGGGAUACCAACCCGCG 17 1023 BCL11A-539 + UACCAACCCGCGGGGUC 17 1024 BCL11A-540 + ACCAACCCGCGGGGUCA 17 1025 BCL11A-541 + CCAACCCGCGGGGUCAG 17 1026 BCL11A-542 + CAAGAGAAACCAUGCAC 17 1027 BCL11A-543 + AACCAUGCACUGGUGAA 17 1028 BCL11A-544 + UGUACAUGUGUAGCUGC 17 1029 BCL11A-545 + GUACAUGUGUAGCUGCU 17 1030 BCL11A-546 - AGAGGAGGAGGAGGAGCUGA 20 1031 BCL11A-547 - AGGAGCUGACGGAGAGCGAG 20 1032 BCL11A-548 - GGAGCUGACGGAGAGCGAGA 20 1033 BCL11A-549 - GCUGACGGAGAGCGAGAGGG 20 1034 BCL11A-550 - GAGAGCGAGAGGGUGGACUA 20 1035 BCL11A-551 - GAGAGGGUGGACUACGGCUU 20 1036 BCL11A-552 - AGAGGGUGGACUACGGCUUC 20 1037 BCL11A-553 - CUACGGCUUCGGGCUGAGCC 20 1038 BCL11A-554 - CGGCUUCGGGCUGAGCCUGG 20 1039 BCL11A-555 - CUUCGGGCUGAGCCUGGAGG 20 1040 BCL11A-556 - GCCACCACGAGAACAGCUCG 20 1041 BCL11A-557 - CCACCACGAGAACAGCUCGC 20 1042 BCL11A-558 - CACCACGAGAACAGCUCGCG 20 1043 BCL11A-559 - CGAGAACAGCUCGCGGGGCG 20 1044 BCL11A-560 - CAGCUCGCGGGGCGCGGUCG 20 1045 BCL11A-561 - AGCUCGCGGGGCGCGGUCGU 20 1046 BCL11A-562 - GCGGGGCGCGGUCGUGGGCG 20 1047 BCL11A-563 - CGGGGCGCGGUCGUGGGCGU 20 1048 BCL11A-564 - CGCCCUGCCCGACGUCAUGC 20 1049 BCL11A-565 - GCCCUGCCCGACGUCAUGCA 20 1050 BCL11A-566 - GCCCGACGUCAUGCAGGGCA 20 1051 BCL11A-567 - CUCCAUGCAGCACUUCAGCG 20 1052 BCL11A-568 - CUUCAGCGAGGCCUUCCACC 20 1053 BCL11A-569 - CGAGGCCUUCCACCAGGUCC 20 1054 BCL11A-570 - GAGGCCUUCCACCAGGUCCU 20 1055 BCL11A-571 - CUGGGCGAGAAGCAUAAGCG 20 1056 BCL11A-572 - GAAGCAUAAGCGCGGCCACC 20 1057 BCL11A-573 - UAAGCGCGGCCACCUGGCCG 20 1058 BCL11A-574 - CGGCCACCUGGCCGAGGCCG 20 1059 BCL11A-575 - GGCCACCUGGCCGAGGCCGA 20 1060 BCL11A-576 - UGGCCGAGGCCGAGGGCCAC 20 1061 BCL11A-577 - GGCCGAGGCCGAGGGCCACA 20 1062 BCL11A-578 - GGACACUUGCGACGAAGACU 20 1063 BCL11A-579 - CACUUGCGACGAAGACUCGG 20 1064 BCL11A-580 - UGCGACGAAGACUCGGUGGC 20 1065 BCL11A-581 - AGACUCGGUGGCCGGCGAGU 20 1066 BCL11A-582 - GAGUCGGACCGCAUAGACGA 20 1067 BCL11A-583 - AUAGACGAUGGCACUGUUAA 20 1068 BCL11A-584 - GAUGGCACUGUUAAUGGCCG 20 1069 BCL11A-585 - UAAUGGCCGCGGCUGCUCCC 20 1070 BCL11A-586 - AAUGGCCGCGGCUGCUCCCC 20 1071 BCL11A-587 - CGGCUGCUCCCCGGGCGAGU 20 1072 BCL11A-588 - CUCCCCGGGCGAGUCGGCCU 20 1073 BCL11A-589 - UCCCCGGGCGAGUCGGCCUC 20 1074 BCL11A-590 - CCCCGGGCGAGUCGGCCUCG 20 1075 BCL11A-591 - CCCGGGCGAGUCGGCCUCGG 20 1076 BCL11A-592 - CCGGGCGAGUCGGCCUCGGG 20 1077 BCL11A-593 - CCUGUCCAAAAAGCUGCUGC 20 1078 BCL11A-594 - CUGUCCAAAAAGCUGCUGCU 20 1079 BCL11A-595 - UAAGCGCAUCAAGCUCGAGA 20 1080 BCL11A-596 - GAAGGAGUUCGACCUGCCCC 20 1081 BCL11A-597 - CCCGGCCGCGAUGCCCAACA 20 1082 BCL11A-598 - CGGAGAACGUGUACUCGCAG 20 1083 BCL11A-599 - GUGUACUCGCAGUGGCUCGC 20 1084 BCL11A-600 - GCAGUGGCUCGCCGGCUACG 20 1085 BCL11A-601 - UCGCCGGCUACGCGGCCUCC 20 1086 BCL11A-602 - AAAGAUCCCUUCCUUAGCUU 20 1087 BCL11A-603 - AUCGCCUUUUGCCUCCUCGU 20 1088 BCL11A-604 - CUCCUCGUCGGAGCACUCCU 20 1089 BCL11A-605 - UCGGAGCACUCCUCGGAGAA 20 1090 BCL11A-606 - CGGAGCACUCCUCGGAGAAC 20 1091 BCL11A-607 - UUGCGCUUCUCCACACCGCC 20 1092 BCL11A-608 - UGCGCUUCUCCACACCGCCC 20 1093 BCL11A-609 - GCGCUUCUCCACACCGCCCG 20 1094 BCL11A-610 - CUCCACACCGCCCGGGGAGC 20 1095 BCL11A-611 - ACACCGCCCGGGGAGCUGGA 20 1096 BCL11A-612 - CCGCCCGGGGAGCUGGACGG 20 1097 BCL11A-613 - CGCCCGGGGAGCUGGACGGA 20 1098 BCL11A-614 - GGAGCUGGACGGAGGGAUCU 20 1099 BCL11A-615 - GAGCUGGACGGAGGGAUCUC 20 1100 BCL11A-616 - AGCUGGACGGAGGGAUCUCG 20 1101 BCL11A-617 - GGAGGGAUCUCGGGGCGCAG 20 1102 BCL11A-618 - GAUCUCGGGGCGCAGCGGCA 20 1103 BCL11A-619 - AUCUCGGGGCGCAGCGGCAC 20 1104 BCL11A-620 - GGGCGCAGCGGCACGGGAAG 20 1105 BCL11A-621 - CGCAGCGGCACGGGAAGUGG 20 1106 BCL11A-622 - GCAGCGGCACGGGAAGUGGA 20 1107 BCL11A-623 - GGGAGCACGCCCCAUAUUAG 20 1108 BCL11A-624 - CACGCCCCAUAUUAGUGGUC 20 1109 BCL11A-625 - ACGCCCCAUAUUAGUGGUCC 20 1110 BCL11A-626 - CCAUAUUAGUGGUCCGGGCC 20 1111 BCL11A-627 - CAUAUUAGUGGUCCGGGCCC 20 1112 BCL11A-628 - UUAGUGGUCCGGGCCCGGGC 20 1113 BCL11A-629 - GGGCAGGCCCAGCUCAAAAG 20 1114 BCL11A-630 - GGCAGGCCCAGCUCAAAAGA 20 1115 BCL11A-631 + GCGUCUGCCCUCUUUUGAGC 20 1116 BCL11A-632 + CGUCUGCCCUCUUUUGAGCU 20 1117 BCL11A-633 + UCUUUUGAGCUGGGCCUGCC 20 1118 BCL11A-634 + CUUUUGAGCUGGGCCUGCCC 20 1119 BCL11A-635 + GAGCUGGGCCUGCCCGGGCC 20 1120 BCL11A-636 + CCGGGCCCGGACCACUAAUA 20 1121 BCL11A-637 + CGGGCCCGGACCACUAAUAU 20 1122 BCL11A-638 + GGGCCCGGACCACUAAUAUG 20 1123 BCL11A-639 + GAUCCCUCCGUCCAGCUCCC 20 1124 BCL11A-640 + AUCCCUCCGUCCAGCUCCCC 20 1125 BCL11A-641 + CCUCCGUCCAGCUCCCCGGG 20 1126 BCL11A-642 + GUCCAGCUCCCCGGGCGGUG 20 1127 BCL11A-643 + GCGCAAACUCCCGUUCUCCG 20 1128 BCL11A-644 + CUCCGAGGAGUGCUCCGACG 20 1129 BCL11A-645 + CGAGGAGUGCUCCGACGAGG 20 1130 BCL11A-646 + UGCUCCGACGAGGAGGCAAA 20 1131 BCL11A-647 + GGAGGCAAAAGGCGAUUGUC 20 1132 BCL11A-648 + GUCUGGAGUCUCCGAAGCUA 20 1133 BCL11A-649 + GGAGUCUCCGAAGCUAAGGA 20 1134 BCL11A-650 + GAGUCUCCGAAGCUAAGGAA 20 1135 BCL11A-651 + GAAGGGAUCUUUGAGCUGCC 20 1136 BCL11A-652 + GGGAUCUUUGAGCUGCCUGG 20 1137 BCL11A-653 + CUGCCUGGAGGCCGCGUAGC 20 1138 BCL11A-654 + CGAGUACACGUUCUCCGUGU 20 1139 BCL11A-655 + GAGUACACGUUCUCCGUGUU 20 1140 BCL11A-656 + GUUCUCCGUGUUGGGCAUCG 20 1141 BCL11A-657 + UCCGUGUUGGGCAUCGCGGC 20 1142 BCL11A-658 + CCGUGUUGGGCAUCGCGGCC 20 1143 BCL11A-659 + CGUGUUGGGCAUCGCGGCCG 20 1144 BCL11A-660 + GUGUUGGGCAUCGCGGCCGG 20 1145 BCL11A-661 + UGGGCAUCGCGGCCGGGGGC 20 1146 BCL11A-662 + GAGCUUGAUGCGCUUAGAGA 20 1147 BCL11A-663 + AGCUUGAUGCGCUUAGAGAA 20 1148 BCL11A-664 + GCUUGAUGCGCUUAGAGAAG 20 1149 BCL11A-665 + AGAGAAGGGGCUCAGCGAGC 20 1150 BCL11A-666 + GAGAAGGGGCUCAGCGAGCU 20 1151 BCL11A-667 + AGAAGGGGCUCAGCGAGCUG 20 1152 BCL11A-668 + GCUGCCCAGCAGCAGCUUUU 20 1153 BCL11A-669 + CCAGCAGCAGCUUUUUGGAC 20 1154 BCL11A-670 + CUUUUUGGACAGGCCCCCCG 20 1155 BCL11A-671 + CCCCCCGAGGCCGACUCGCC 20 1156 BCL11A-672 + CCCCCGAGGCCGACUCGCCC 20 1157 BCL11A-673 + CCCCGAGGCCGACUCGCCCG 20 1158 BCL11A-674 + ACUCGCCCGGGGAGCAGCCG 20 1159 BCL11A-675 + UAACAGUGCCAUCGUCUAUG 20 1160 BCL11A-676 + GUCUAUGCGGUCCGACUCGC 20 1161 BCL11A-677 + CUUCGUCGCAAGUGUCCCUG 20 1162 BCL11A-678 + GCAAGUGUCCCUGUGGCCCU 20 1163 BCL11A-679 + GUCCCUGUGGCCCUCGGCCU 20 1164 BCL11A-680 + UGUGGCCCUCGGCCUCGGCC 20 1165 BCL11A-681 + GGCCCUCGGCCUCGGCCAGG 20 1166 BCL11A-682 + CGCGCUUAUGCUUCUCGCCC 20 1167 BCL11A-683 + UAUGCUUCUCGCCCAGGACC 20 1168 BCL11A-684 + GCUUCUCGCCCAGGACCUGG 20 1169 BCL11A-685 + CUCGCCCAGGACCUGGUGGA 20 1170 BCL11A-686 + GGCCUCGCUGAAGUGCUGCA 20 1171 BCL11A-687 + CACCAUGCCCUGCAUGACGU 20 1172 BCL11A-688 + ACCAUGCCCUGCAUGACGUC 20 1173 BCL11A-689 + UGCCCUGCAUGACGUCGGGC 20 1174 BCL11A-690 + GCCCUGCAUGACGUCGGGCA 20 1175 BCL11A-691 + GCAUGACGUCGGGCAGGGCG 20 1176 BCL11A-692 + CGCCCCGCGAGCUGUUCUCG 20 1177 BCL11A-693 + CCCGCGAGCUGUUCUCGUGG 20 1178 BCL11A-694 + CGUGGUGGCGCGCCGCCUCC 20 1179 BCL11A-695 - GGAGGAAGAGGAGGAGG 17 1180 BCL11A-696 - GGAGGAGGAGGAGCUGA 17 1181 BCL11A-697 - AGCUGACGGAGAGCGAG 17 1182 BCL11A-698 - GCUGACGGAGAGCGAGA 17 1183 BCL11A-699 - GACGGAGAGCGAGAGGG 17 1184 BCL11A-700 - AGCGAGAGGGUGGACUA 17 1185 BCL11A-701 - AGGGUGGACUACGGCUU 17 1186 BCL11A-702 - GGGUGGACUACGGCUUC 17 1187 BCL11A-703 - CGGCUUCGGGCUGAGCC 17 1188 BCL11A-704 - CUUCGGGCUGAGCCUGG 17 1189 BCL11A-705 - CGGGCUGAGCCUGGAGG 17 1190 BCL11A-706 - ACCACGAGAACAGCUCG 17 1191 BCL11A-707 - CCACGAGAACAGCUCGC 17 1192 BCL11A-708 - CACGAGAACAGCUCGCG 17 1193 BCL11A-709 - GAACAGCUCGCGGGGCG 17 1194 BCL11A-710 - CUCGCGGGGCGCGGUCG 17 1195 BCL11A-711 - UCGCGGGGCGCGGUCGU 17 1196 BCL11A-712 - GGGCGCGGUCGUGGGCG 17 1197 BCL11A-713 - GGCGCGGUCGUGGGCGU 17 1198 BCL11A-714 - CCUGCCCGACGUCAUGC 17 1199 BCL11A-715 - CUGCCCGACGUCAUGCA 17 1200 BCL11A-716 - CGACGUCAUGCAGGGCA 17 1201 BCL11A-717 - CAUGCAGCACUUCAGCG 17 1202 BCL11A-718 - CAGCGAGGCCUUCCACC 17 1203 BCL11A-719 - GGCCUUCCACCAGGUCC 17 1204 BCL11A-720 - GCCUUCCACCAGGUCCU 17 1205 BCL11A-721 - GGCGAGAAGCAUAAGCG 17 1206 BCL11A-722 - GCAUAAGCGCGGCCACC 17 1207 BCL11A-723 - GCGCGGCCACCUGGCCG 17 1208 BCL11A-724 - CCACCUGGCCGAGGCCG 17 1209 BCL11A-725 - CACCUGGCCGAGGCCGA 17 1210 BCL11A-726 - CCGAGGCCGAGGGCCAC 17 1211 BCL11A-727 - CGAGGCCGAGGGCCACA 17 1212 BCL11A-728 - CACUUGCGACGAAGACU 17 1213 BCL11A-729 - UUGCGACGAAGACUCGG 17 1214 BCL11A-730 - GACGAAGACUCGGUGGC 17 1215 BCL11A-731 - CUCGGUGGCCGGCGAGU 17 1216 BCL11A-732 - UCGGACCGCAUAGACGA 17 1217 BCL11A-733 - GACGAUGGCACUGUUAA 17 1218 BCL11A-734 - GGCACUGUUAAUGGCCG 17 1219 BCL11A-735 - UGGCCGCGGCUGCUCCC 17 1220 BCL11A-736 - GGCCGCGGCUGCUCCCC 17 1221 BCL11A-737 - CUGCUCCCCGGGCGAGU 17 1222 BCL11A-738 - CCCGGGCGAGUCGGCCU 17 1223 BCL11A-739 - CCGGGCGAGUCGGCCUC 17 1224 BCL11A-740 - CGGGCGAGUCGGCCUCG 17 1225 BCL11A-741 - GGGCGAGUCGGCCUCGG 17 1226 BCL11A-742 - GGCGAGUCGGCCUCGGG 17 1227 BCL11A-743 - GUCCAAAAAGCUGCUGC 17 1228 BCL11A-744 - UCCAAAAAGCUGCUGCU 17 1229 BCL11A-745 - GCGCAUCAAGCUCGAGA 17 1230 BCL11A-746 - GGAGUUCGACCUGCCCC 17 1231 BCL11A-747 - GGCCGCGAUGCCCAACA 17 1232 BCL11A-748 - AGAACGUGUACUCGCAG 17 1233 BCL11A-749 - UACUCGCAGUGGCUCGC 17 1234 BCL11A-750 - GUGGCUCGCCGGCUACG 17 1235 BCL11A-751 - CCGGCUACGCGGCCUCC 17 1236 BCL11A-752 - GAUCCCUUCCUUAGCUU 17 1237 BCL11A-753 - GCCUUUUGCCUCCUCGU 17 1238 BCL11A-754 - CUCGUCGGAGCACUCCU 17 1239 BCL11A-755 - GAGCACUCCUCGGAGAA 17 1240 BCL11A-756 - AGCACUCCUCGGAGAAC 17 1241 BCL11A-757 - CGCUUCUCCACACCGCC 17 1242 BCL11A-758 - GCUUCUCCACACCGCCC 17 1243 BCL11A-759 - CUUCUCCACACCGCCCG 17 1244 BCL11A-760 - CACACCGCCCGGGGAGC 17 1245 BCL11A-761 - CCGCCCGGGGAGCUGGA 17 1246 BCL11A-762 - CCCGGGGAGCUGGACGG 17 1247 BCL11A-763 - CCGGGGAGCUGGACGGA 17 1248 BCL11A-764 - GCUGGACGGAGGGAUCU 17 1249 BCL11A-765 - CUGGACGGAGGGAUCUC 17 1250 BCL11A-766 - UGGACGGAGGGAUCUCG 17 1251 BCL11A-767 - GGGAUCUCGGGGCGCAG 17 1252 BCL11A-768 - CUCGGGGCGCAGCGGCA 17 1253 BCL11A-769 - UCGGGGCGCAGCGGCAC 17 1254 BCL11A-770 - CGCAGCGGCACGGGAAG 17 1255 BCL11A-771 - AGCGGCACGGGAAGUGG 17 1256 BCL11A-772 - GCGGCACGGGAAGUGGA 17 1257 BCL11A-773 - AGCACGCCCCAUAUUAG 17 1258 BCL11A-774 - GCCCCAUAUUAGUGGUC 17 1259 BCL11A-775 - CCCCAUAUUAGUGGUCC 17 1260 BCL11A-776 - UAUUAGUGGUCCGGGCC 17 1261 BCL11A-777 - AUUAGUGGUCCGGGCCC 17 1262 BCL11A-778 - GUGGUCCGGGCCCGGGC 17 1263 BCL11A-779 - CAGGCCCAGCUCAAAAG 17 1264 BCL11A-780 - AGGCCCAGCUCAAAAGA 17 1265 BCL11A-781 + UCUGCCCUCUUUUGAGC 17 1266 BCL11A-782 + CUGCCCUCUUUUGAGCU 17 1267 BCL11A-783 + UUUGAGCUGGGCCUGCC 17 1268 BCL11A-784 + UUGAGCUGGGCCUGCCC 17 1269 BCL11A-785 + CUGGGCCUGCCCGGGCC 17 1270 BCL11A-786 + GGCCCGGACCACUAAUA 17 1271 BCL11A-787 + GCCCGGACCACUAAUAU 17 1272 BCL11A-788 + CCCGGACCACUAAUAUG 17 1273 BCL11A-789 + CCCUCCGUCCAGCUCCC 17 1274 BCL11A-790 + CCUCCGUCCAGCUCCCC 17 1275 BCL11A-791 + CCGUCCAGCUCCCCGGG 17 1276 BCL11A-792 + CAGCUCCCCGGGCGGUG 17 1277 BCL11A-793 + CAAACUCCCGUUCUCCG 17 1278 BCL11A-794 + CGAGGAGUGCUCCGACG 17 1279 BCL11A-795 + GGAGUGCUCCGACGAGG 17 1280 BCL11A-796 + UCCGACGAGGAGGCAAA 17 1281 BCL11A-797 + GGCAAAAGGCGAUUGUC 17 1282 BCL11A-798 + UGGAGUCUCCGAAGCUA 17 1283 BCL11A-799 + GUCUCCGAAGCUAAGGA 17 1284 BCL11A-800 + UCUCCGAAGCUAAGGAA 17 1285 BCL11A-801 + GGGAUCUUUGAGCUGCC 17 1286 BCL11A-802 + AUCUUUGAGCUGCCUGG 17 1287 BCL11A-803 + CCUGGAGGCCGCGUAGC 17 1288 BCL11A-804 + GUACACGUUCUCCGUGU 17 1289 BCL11A-805 + UACACGUUCUCCGUGUU 17 1290 BCL11A-806 + CUCCGUGUUGGGCAUCG 17 1291 BCL11A-807 + GUGUUGGGCAUCGCGGC 17 1292 BCL11A-808 + UGUUGGGCAUCGCGGCC 17 1293 BCL11A-809 + GUUGGGCAUCGCGGCCG 17 1294 BCL11A-810 + UUGGGCAUCGCGGCCGG 17 1295 BCL11A-811 + GCAUCGCGGCCGGGGGC 17 1296 BCL11A-812 + CUUGAUGCGCUUAGAGA 17 1297 BCL11A-813 + UUGAUGCGCUUAGAGAA 17 1298 BCL11A-814 + UGAUGCGCUUAGAGAAG 17 1299 BCL11A-815 + GAAGGGGCUCAGCGAGC 17 1300 BCL11A-816 + AAGGGGCUCAGCGAGCU 17 1301 BCL11A-817 + AGGGGCUCAGCGAGCUG 17 1302 BCL11A-818 + GCCCAGCAGCAGCUUUU 17 1303 BCL11A-819 + GCAGCAGCUUUUUGGAC 17 1304 BCL11A-820 + UUUGGACAGGCCCCCCG 17 1305 BCL11A-821 + CCCGAGGCCGACUCGCC 17 1306 BCL11A-822 + CCGAGGCCGACUCGCCC 17 1307 BCL11A-823 + CGAGGCCGACUCGCCCG 17 1308 BCL11A-824 + CGCCCGGGGAGCAGCCG 17 1309 BCL11A-825 + CAGUGCCAUCGUCUAUG 17 1310 BCL11A-826 + UAUGCGGUCCGACUCGC 17 1311 BCL11A-827 + CGUCGCAAGUGUCCCUG 17 1312 BCL11A-828 + AGUGUCCCUGUGGCCCU 17 1313 BCL11A-829 + CCUGUGGCCCUCGGCCU 17 1314 BCL11A-830 + GGCCCUCGGCCUCGGCC 17 1315 BCL11A-831 + CCUCGGCCUCGGCCAGG 17 1316 BCL11A-832 + GCUUAUGCUUCUCGCCC 17 1317 BCL11A-833 + GCUUCUCGCCCAGGACC 17 1318 BCL11A-834 + UCUCGCCCAGGACCUGG 17 1319 BCL11A-835 + GCCCAGGACCUGGUGGA 17 1320 BCL11A-836 + CUCGCUGAAGUGCUGCA 17 1321 BCL11A-837 + CAUGCCCUGCAUGACGU 17 1322 BCL11A-838 + AUGCCCUGCAUGACGUC 17 1323 BCL11A-839 + CCUGCAUGACGUCGGGC 17 1324 BCL11A-840 + CUGCAUGACGUCGGGCA 17 1325 BCL11A-841 + UGACGUCGGGCAGGGCG 17 1326 BCL11A-842 + CCCGCGAGCUGUUCUCG 17 1327 BCL11A-843 + GCGAGCUGUUCUCGUGG 17 1328 BCL11A-844 + GGUGGCGCGCCGCCUCC 17 1329 BCL11A-845 - CCCAGAGAGCUCAAGAUGUG 20 1330 BCL11A-846 - UCAAGAUGUGUGGCAGUUUU 20 1331 BCL11A-847 - GAUGUGUGGCAGUUUUCGGA 20 1332 BCL11A-848 + GCCACACAUCUUGAGCUCUC 20 1333 BCL11A-849 + CCACACAUCUUGAGCUCUCU 20 1334 BCL11A-850 + UCUCUGGGUACUACGCCGAA 20 1335 BCL11A-851 + CUCUGGGUACUACGCCGAAU 20 1336 BCL11A-852 + UCUGGGUACUACGCCGAAUG 20 1337 BCL11A-853 + CUGGGUACUACGCCGAAUGG 20 1338 BCL11A-854 - CUUCACACACCCCCAUU 17 1339 BCL11A-855 - AGAGAGCUCAAGAUGUG 17 1340 BCL11A-856 - AGAUGUGUGGCAGUUUU 17 1341 BCL11A-857 - GUGUGGCAGUUUUCGGA 17 1342 BCL11A-858 + ACACAUCUUGAGCUCUC 17 1343 BCL11A-859 + CACAUCUUGAGCUCUCU 17 1344 BCL11A-860 + CUGGGUACUACGCCGAA 17 1345 BCL11A-861 + UGGGUACUACGCCGAAU 17 1346 BCL11A-862 + GGGUACUACGCCGAAUG 17 1347 BCL11A-863 + GGUACUACGCCGAAUGG 17 1348

Table 2E provides exemplary targeting domains for knocking out the BCL11A gene. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that gives double stranded cleavage. Any of the targeting domains in the table can be used with a S. aureus Cas9 single-stranded break nucleases (nickases). In an embodiment, dual targeting is used to create two nicks. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position.

TABLE 2E S. aureus gRNA targets for BCL11A knockout DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-864 - AAACCCCAGCACUUAAGCAA 20 1349 BCL11A-865 - AACCCCAGCACUUAAGCAAA 20 1350 BCL11A-866 - ACCCCAGCACUUAAGCAAAC 20 1351 BCL11A-867 - CCCCAGCACUUAAGCAA 17 1352 BCL11A-868 - CCCAGCACUUAAGCAAA 17 1353 BCL11A-869 - CCAGCACUUAAGCAAAC 17 1354 BCL11A-870 + UGGGGUUUGCCUUGCUUGCG 20 1355 BCL11A-871 + AUUCCCGUUUGCUUAAGUGC 20 1356 BCL11A-872 + AAUUCCCGUUUGCUUAAGUG 20 1357 BCL11A-873 + GGUUUGCCUUGCUUGCG 17 1358 BCL11A-874 + CCCGUUUGCUUAAGUGC 17 1359 BCL11A-875 + UCCCGUUUGCUUAAGUG 17 1360 BCL11A-876 - UGAAGCCAUUCUUACAGAUG 20 1361 BCL11A-877 - AUGAACCAGACCACGGCCCG 20 1362 BCL11A-878 - UGAACCAGACCACGGCCCGU 20 1363 BCL11A-879 - GAACCAGACCACGGCCCGUU 20 1364 BCL11A-880 - CCACGGCCCGUUGGGAGCUC 20 1365 BCL11A-881 - CGGCCCGUUGGGAGCUCCAG 20 1366 BCL11A-882 - GGCCCGUUGGGAGCUCCAGA 20 1367 BCL11A-883 - GCCCGUUGGGAGCUCCAGAA 20 1368 BCL11A-884 - GGAUCAUGACCUCCUCACCU 20 1369 BCL11A-885 - UCACCUGUGGGCAGUGCCAG 20 1370 BCL11A-886 - AGUGCCAGAUGAACUUCCCA 20 1371 BCL11A-887 - GUGCCAGAUGAACUUCCCAU 20 1372 BCL11A-888 - UGCCAGAUGAACUUCCCAUU 20 1373 BCL11A-889 - GCCAGAUGAACUUCCCAUUG 20 1374 BCL11A-890 - GGGGGACAUUCUUAUUUUUA 20 1375 BCL11A-891 - CUUAUUUUUAUCGAGCACAA 20 1376 BCL11A-892 - UUAUUUUUAUCGAGCACAAA 20 1377 BCL11A-893 - AUGCAAUGGCAGCCUCUGCU 20 1378 BCL11A-894 - GCCUCUGCUUAGAAAAAGCU 20 1379 BCL11A-895 - GCCACCUUCCCCUUCACCAA 20 1380 BCL11A-896 - CUUCCCCUUCACCAAUCGAG 20 1381 BCL11A-897 - UGAAAAAAGCAUCCAAUCCC 20 1382 BCL11A-898 - GAAAAAAGCAUCCAAUCCCG 20 1383 BCL11A-899 - GGUUGGCAUCCAGGUCACGC 20 1384 BCL11A-900 - UUGGCAUCCAGGUCACGCCA 20 1385 BCL11A-901 - GAUUGUUUAUCAACGUCAUC 20 1386 BCL11A-902 - UUGUUUAUCAACGUCAUCUA 20 1387 BCL11A-903 - UGUUUAUCAACGUCAUCUAG 20 1388 BCL11A-904 - CUAGAGGAAUUUGCCCCAAA 20 1389 BCL11A-905 - UAGAGGAAUUUGCCCCAAAC 20 1390 BCL11A-906 - AGCCAUUCUUACAGAUG 17 1391 BCL11A-907 - AACCAGACCACGGCCCG 17 1392 BCL11A-908 - ACCAGACCACGGCCCGU 17 1393 BCL11A-909 - CCAGACCACGGCCCGUU 17 1394 BCL11A-910 - CGGCCCGUUGGGAGCUC 17 1395 BCL11A-911 - CCCGUUGGGAGCUCCAG 17 1396 BCL11A-912 - CCGUUGGGAGCUCCAGA 17 1397 BCL11A-913 - CGUUGGGAGCUCCAGAA 17 1398 BCL11A-914 - UCAUGACCUCCUCACCU 17 1399 BCL11A-915 - CCUGUGGGCAGUGCCAG 17 1400 BCL11A-916 - GCCAGAUGAACUUCCCA 17 1401 BCL11A-917 - CCAGAUGAACUUCCCAU 17 1402 BCL11A-918 - CAGAUGAACUUCCCAUU 17 1403 BCL11A-919 - AGAUGAACUUCCCAUUG 17 1404 BCL11A-920 - GGACAUUCUUAUUUUUA 17 1405 BCL11A-921 - AUUUUUAUCGAGCACAA 17 1406 BCL11A-922 - UUUUUAUCGAGCACAAA 17 1407 BCL11A-923 - CAAUGGCAGCCUCUGCU 17 1408 BCL11A-924 - UCUGCUUAGAAAAAGCU 17 1409 BCL11A-925 - ACCUUCCCCUUCACCAA 17 1410 BCL11A-926 - CCCCUUCACCAAUCGAG 17 1411 BCL11A-927 - AAAAAGCAUCCAAUCCC 17 1412 BCL11A-928 - AAAAGCAUCCAAUCCCG 17 1413 BCL11A-929 - UGGCAUCCAGGUCACGC 17 1414 BCL11A-930 - GCAUCCAGGUCACGCCA 17 1415 BCL11A-931 - UGUUUAUCAACGUCAUC 17 1416 BCL11A-932 - UUUAUCAACGUCAUCUA 17 1417 BCL11A-933 - UUAUCAACGUCAUCUAG 17 1418 BCL11A-934 - GAGGAAUUUGCCCCAAA 17 1419 BCL11A-935 - AGGAAUUUGCCCCAAAC 17 1420 BCL11A-936 + UCAUCUGUAAGAAUGGCUUC 20 1421 BCL11A-937 + UGGUCUGGUUCAUCAUCUGU 20 1422 BCL11A-938 + AUCCCCUUCUGGAGCUCCCA 20 1423 BCL11A-939 + AGGAGGUCAUGAUCCCCUUC 20 1424 BCL11A-940 + GAGGAGGUCAUGAUCCCCUU 20 1425 BCL11A-941 + UCUGGCACUGCCCACAGGUG 20 1426 BCL11A-942 + AUCUGGCACUGCCCACAGGU 20 1427 BCL11A-943 + UCAUCUGGCACUGCCCACAG 20 1428 BCL11A-944 + AAAUAAGAAUGUCCCCCAAU 20 1429 BCL11A-945 + AAAAUAAGAAUGUCCCCCAA 20 1430 BCL11A-946 + AAAAAUAAGAAUGUCCCCCA 20 1431 BCL11A-947 + CGUUUGUGCUCGAUAAAAAU 20 1432 BCL11A-948 + UAUCCACAGCUUUUUCUAAG 20 1433 BCL11A-949 + UUUCAUCUCGAUUGGUGAAG 20 1434 BCL11A-950 + UUUUCAUCUCGAUUGGUGAA 20 1435 BCL11A-951 + UUUUUCAUCUCGAUUGGUGA 20 1436 BCL11A-952 + UUUUUUCAUCUCGAUUGGUG 20 1437 BCL11A-953 + UGCUUUUUUCAUCUCGAUUG 20 1438 BCL11A-954 + GGAUGCCAACCUCCACGGGA 20 1439 BCL11A-955 + GACCUGGAUGCCAACCUCCA 20 1440 BCL11A-956 + UGACCUGGAUGCCAACCUCC 20 1441 BCL11A-957 + UCGUCAUCCUCUGGCGUGAC 20 1442 BCL11A-958 + CUGCUAUGUGUUCCUGUUUG 20 1443 BCL11A-959 + CUGCUAUGUGUUCCUGUUUG 20 1444 BCL11A-960 + UCUGUAAGAAUGGCUUC 17 1445 BCL11A-961 + UCUGGUUCAUCAUCUGU 17 1446 BCL11A-962 + CCCUUCUGGAGCUCCCA 17 1447 BCL11A-963 + AGGUCAUGAUCCCCUUC 17 1448 BCL11A-964 + GAGGUCAUGAUCCCCUU 17 1449 BCL11A-965 + GGCACUGCCCACAGGUG 17 1450 BCL11A-966 + UGGCACUGCCCACAGGU 17 1451 BCL11A-967 + UCUGGCACUGCCCACAG 17 1452 BCL11A-968 + UAAGAAUGUCCCCCAAU 17 1453 BCL11A-969 + AUAAGAAUGUCCCCCAA 17 1454 BCL11A-970 + AAUAAGAAUGUCCCCCA 17 1455 BCL11A-971 + UUGUGCUCGAUAAAAAU 17 1456 BCL11A-972 + CCACAGCUUUUUCUAAG 17 1457 BCL11A-973 + CAUCUCGAUUGGUGAAG 17 1458 BCL11A-974 + UCAUCUCGAUUGGUGAA 17 1459 BCL11A-975 + UUCAUCUCGAUUGGUGA 17 1460 BCL11A-976 + UUUCAUCUCGAUUGGUG 17 1461 BCL11A-977 + UUUUUUCAUCUCGAUUG 17 1462 BCL11A-978 + UGCCAACCUCCACGGGA 17 1463 BCL11A-979 + CUGGAUGCCAACCUCCA 17 1464 BCL11A-980 + CCUGGAUGCCAACCUCC 17 1465 BCL11A-981 + UCAUCCUCUGGCGUGAC 17 1466 BCL11A-982 + UGCUAUGUGUUCCUGUU 17 1467 BCL11A-983 + CUGCUAUGUGUUCCUGU 17 1468 BCL11A-984 - CUCCUCCCCUCGUUCUGCAC 20 1469 BCL11A-985 - UCCUCCCCUCGUUCUGCACA 20 1470 BCL11A-986 - UGGAGCUCUAAUCCCCACGC 20 1471 BCL11A-987 - GGAGCUCUAAUCCCCACGCC 20 1472 BCL11A-988 - CUCUAAUCCCCACGCCUGGG 20 1473 BCL11A-989 - CCCCACGCCUGGGAUGAGUG 20 1474 BCL11A-990 - UGAGUGCAGAAUAUGCCCCG 20 1475 BCL11A-991 - CUCCCCUCGUUCUGCAC 17 1476 BCL11A-992 - UCCCCUCGUUCUGCACA 17 1477 BCL11A-993 - AGCUCUAAUCCCCACGC 17 1478 BCL11A-994 - GCUCUAAUCCCCACGCC 17 1479 BCL11A-995 - UAAUCCCCACGCCUGGG 17 1480 BCL11A-996 - CACGCCUGGGAUGAGUG 17 1481 BCL11A-997 - GUGCAGAAUAUGCCCCG 17 1482 BCL11A-998 + GAGGAGAGGCCCCUCCAGUG 20 1483 BCL11A-999 + CAUGUGCAGAACGAGGGGAG 20 1484 BCL11A-1000 + UCCAUGUGCAGAACGAGGGG 20 1485 BCL11A-1001 + CUCCAUGUGCAGAACGAGGG 20 1486 BCL11A-1002 + AGCUCCAUGUGCAGAACGAG 20 1487 BCL11A-1003 + GAGCUCCAUGUGCAGAACGA 20 1488 BCL11A-1004 + AGAGCUCCAUGUGCAGAACG 20 1489 BCL11A-1005 + UAGAGCUCCAUGUGCAGAAC 20 1490 BCL11A-1006 + AUUAGAGCUCCAUGUGCAGA 20 1491 BCL11A-1007 + GGGGAUUAGAGCUCCAUGUG 20 1492 BCL11A-1008 + CUCAUCCCAGGCGUGGGGAU 20 1493 BCL11A-1009 + UCUGCACUCAUCCCAGGCGU 20 1494 BCL11A-1010 + UUCUGCACUCAUCCCAGGCG 20 1495 BCL11A-1011 + AUUCUGCACUCAUCCCAGGC 20 1496 BCL11A-1012 + GAGAGGCCCCUCCAGUG 17 1497 BCL11A-1013 + GUGCAGAACGAGGGGAG 17 1498 BCL11A-1014 + AUGUGCAGAACGAGGGG 17 1499 BCL11A-1015 + CAUGUGCAGAACGAGGG 17 1500 BCL11A-1016 + UCCAUGUGCAGAACGAG 17 1501 BCL11A-1017 + CUCCAUGUGCAGAACGA 17 1502 BCL11A-1018 + GCUCCAUGUGCAGAACG 17 1503 BCL11A-1019 + AGCUCCAUGUGCAGAAC 17 1504 BCL11A-1020 + AGAGCUCCAUGUGCAGA 17 1505 BCL11A-1021 + GAUUAGAGCUCCAUGUG 17 1506 BCL11A-1022 + AUCCCAGGCGUGGGGAU 17 1507 BCL11A-1023 + GCACUCAUCCCAGGCGU 17 1508 BCL11A-1024 + UGCACUCAUCCCAGGCG 17 1509 BCL11A-1025 + CUGCACUCAUCCCAGGC 17 1510 BCL11A-1026 - GGUUUCUCUUGCAACACGCA 20 1511 BCL11A-1027 - GCAACACGCACAGAACACUC 20 1512 BCL11A-1028 - GCACAGAACACUCAUGGAUU 20 1513 BCL11A-1029 - UCAUGGAUUAAGAAUCUACU 20 1514 BCL11A-1030 - AUUAAGAAUCUACUUAGAAA 20 1515 BCL11A-1031 - AAUCUACUUAGAAAGCGAAC 20 1516 BCL11A-1032 - AUCUACUUAGAAAGCGAACA 20 1517 BCL11A-1033 - CACGGAAGUCCCCUGACCCC 20 1518 BCL11A-1034 - CCCGCGGGUUGGUAUCCCUU 20 1519 BCL11A-1035 - UAUCCCUUCAGGACUAGGUG 20 1520 BCL11A-1036 - UCCUUCCCAGCCACCUCUCC 20 1521 BCL11A-1037 - CCUUCCCAGCCACCUCUCCA 20 1522 BCL11A-1038 - AAUAACCCCUUUAACCUGCU 20 1523 BCL11A-1039 - CUUUAACCUGCUAAGAAUAC 20 1524 BCL11A-1040 - UAAGAAUACCAGGAUCAGUA 20 1525 BCL11A-1041 - AGAAUACCAGGAUCAGUAUC 20 1526 BCL11A-1042 - AAUACCAGGAUCAGUAUCGA 20 1527 BCL11A-1043 - GAGAGAGGCUUCCGGCCUGG 20 1528 BCL11A-1044 - AGAGGCUUCCGGCCUGGCAG 20 1529 BCL11A-1045 - CCCCCCUGUUUAGUCCACCA 20 1530 BCL11A-1046 - GUCCACCACCGAGACAUCAC 20 1531 BCL11A-1047 - UCACUUGGACCCCCACCGCA 20 1532 BCL11A-1048 - ACCCCCACCGCAUAGAGCGC 20 1533 BCL11A-1049 - CCCCCACCGCAUAGAGCGCC 20 1534 BCL11A-1050 - CCCCACCGCAUAGAGCGCCU 20 1535 BCL11A-1051 - ACCGCAUAGAGCGCCUGGGG 20 1536 BCL11A-1052 - CCGCAUAGAGCGCCUGGGGG 20 1537 BCL11A-1053 - CAUAGAGCGCCUGGGGGCGG 20 1538 BCL11A-1054 - UGGCCCUGGCCACCCAUCAC 20 1539 BCL11A-1055 - CAUCACCCGAGUGCCUUUGA 20 1540 BCL11A-1056 - CCUUUGACAGGGUGCUGCGG 20 1541 BCL11A-1057 - UGCGGUUGAAUCCAAUGGCU 20 1542 BCL11A-1058 - GCGGUUGAAUCCAAUGGCUA 20 1543 BCL11A-1059 - UGGCUAUGGAGCCUCCCGCC 20 1544 BCL11A-1060 - CCUCCCGCCAUGGAUUUCUC 20 1545 BCL11A-1061 - CUCCCGCCAUGGAUUUCUCU 20 1546 BCL11A-1062 - AUGGAUUUCUCUAGGAGACU 20 1547 BCL11A-1063 - GGAUUUCUCUAGGAGACUUA 20 1548 BCL11A-1064 - UAGGAGACUUAGAGAGCUGG 20 1549 BCL11A-1065 - AGGAGACUUAGAGAGCUGGC 20 1550 BCL11A-1066 - GGAGACUUAGAGAGCUGGCA 20 1551 BCL11A-1067 - CCCGGUCAAGUCCAAGUCAU 20 1552 BCL11A-1068 - GCGGCAAGACGUUCAAAUUU 20 1553 BCL11A-1069 - UGGUGCACCGGCGCAGCCAC 20 1554 BCL11A-1070 - GCACCGGCGCAGCCACACGG 20 1555 BCL11A-1071 - ACCGGCGCAGCCACACGGGC 20 1556 BCL11A-1072 - CGUGCACCCAGGCCAGCAAG 20 1557 BCL11A-1073 - CCAGCAAGCUGAAGCGCCAC 20 1558 BCL11A-1074 - GUCUCUCCACCGCCAGCUCC 20 1559 BCL11A-1075 - UCUCUCCACCGCCAGCUCCC 20 1560 BCL11A-1076 - AACCCGGCACCAGCGACUUG 20 1561 BCL11A-1077 - AGUCCGUGGUGGCCAAGUUC 20 1562 BCL11A-1078 - CGUGGUGGCCAAGUUCAAGA 20 1563 BCL11A-1079 - UGGUGGCCAAGUUCAAGAGC 20 1564 BCL11A-1080 - AGAACGACCCCAACCUGAUC 20 1565 BCL11A-1081 - GAACGACCCCAACCUGAUCC 20 1566 BCL11A-1082 - ACGACCCCAACCUGAUCCCG 20 1567 BCL11A-1083 - CCCCAACCUGAUCCCGGAGA 20 1568 BCL11A-1084 - CCCAACCUGAUCCCGGAGAA 20 1569 BCL11A-1085 - CCAACCUGAUCCCGGAGAAC 20 1570 BCL11A-1086 - CCUGAUCCCGGAGAACGGGG 20 1571 BCL11A-1087 - UGAUCCCGGAGAACGGGGAC 20 1572 BCL11A-1088 - GAUCCCGGAGAACGGGGACG 20 1573 BCL11A-1089 - UCCCGGAGAACGGGGACGAG 20 1574 BCL11A-1090 - CCCGGAGAACGGGGACGAGG 20 1575 BCL11A-1091 - GGAGAACGGGGACGAGGAGG 20 1576 BCL11A-1092 - AGAACGGGGACGAGGAGGAA 20 1577 BCL11A-1093 - GAACGGGGACGAGGAGGAAG 20 1578 BCL11A-1094 - ACGGGGACGAGGAGGAAGAG 20 1579 BCL11A-1095 - CGAGGAGGAAGAGGAGGACG 20 1580 BCL11A-1096 - AGGAGGAAGAGGAGGACGAC 20 1581 BCL11A-1097 - GGAGGAAGAGGAGGACGACG 20 1582 BCL11A-1098 - GGAAGAGGAGGACGACGAGG 20 1583 BCL11A-1099 - AAGAGGAGGACGACGAGGAA 20 1584 BCL11A-1100 - AGAGGAGGACGACGAGGAAG 20 1585 BCL11A-1101 - GGAGGACGACGAGGAAGAGG 20 1586 BCL11A-1102 - GGACGACGAGGAAGAGGAAG 20 1587 BCL11A-1103 - ACGACGAGGAAGAGGAAGAA 20 1588 BCL11A-1104 - CGACGAGGAAGAGGAAGAAG 20 1589 BCL11A-1105 - ACGAGGAAGAGGAAGAAGAG 20 1590 BCL11A-1106 - CGAGGAAGAGGAAGAAGAGG 20 1591 BCL11A-1107 - GGAAGAGGAAGAAGAGGAGG 20 1592 BCL11A-1108 - AAGAGGAAGAAGAGGAGGAA 20 1593 BCL11A-1109 - AGAGGAAGAAGAGGAGGAAG 20 1594 BCL11A-1110 - AGGAAGAAGAGGAGGAAGAG 20 1595 BCL11A-1111 - GGAAGAAGAGGAGGAAGAGG 20 1596 BCL11A-1112 - AAGAAGAGGAGGAAGAGGAG 20 1597 BCL11A-1113 - AGAAGAGGAGGAAGAGGAGG 20 1598 BCL11A-1114 - AAGAGGAGGAAGAGGAGGAG 20 1599 BCL11A-1115 - AGAGGAGGAAGAGGAGGAGG 20 1600 BCL11A-1116 - AAGAGGAGGAGGAGGAGCUG 20 1601 BCL11A-1117 - AGAGGAGGAGGAGGAGCUGA 20 1602 BCL11A-1118 - AGGAGGAGGAGGAGCUGACG 20 1603 BCL11A-1119 - GGAGGAGGAGCUGACGGAGA 20 1604 BCL11A-1120 - AGGAGGAGCUGACGGAGAGC 20 1605 BCL11A-1121 - GAGGAGCUGACGGAGAGCGA 20 1606 BCL11A-1122 - AGCUGACGGAGAGCGAGAGG 20 1607 BCL11A-1123 - CGAGAGGGUGGACUACGGCU 20 1608 BCL11A-1124 - GGGUGGACUACGGCUUCGGG 20 1609 BCL11A-1125 - ACUACGGCUUCGGGCUGAGC 20 1610 BCL11A-1126 - CUACGGCUUCGGGCUGAGCC 20 1611 BCL11A-1127 - CCUGGAGGCGGCGCGCCACC 20 1612 BCL11A-1128 - UGGAGGCGGCGCGCCACCAC 20 1613 BCL11A-1129 - CGCCACCACGAGAACAGCUC 20 1614 BCL11A-1130 - GCCACCACGAGAACAGCUCG 20 1615 BCL11A-1131 - ACAGCUCGCGGGGCGCGGUC 20 1616 BCL11A-1132 - CGCGGGGCGCGGUCGUGGGC 20 1617 BCL11A-1133 - CGCGGUCGUGGGCGUGGGCG 20 1618 BCL11A-1134 - CGGUCGUGGGCGUGGGCGAC 20 1619 BCL11A-1135 - GCGCCCUGCCCGACGUCAUG 20 1620 BCL11A-1136 - CAGCUCCAUGCAGCACUUCA 20 1621 BCL11A-1137 - GCGAGGCCUUCCACCAGGUC 20 1622 BCL11A-1138 - GGCCUUCCACCAGGUCCUGG 20 1623 BCL11A-1139 - CCUUCCACCAGGUCCUGGGC 20 1624 BCL11A-1140 - GCAUAAGCGCGGCCACCUGG 20 1625 BCL11A-1141 - GCGCGGCCACCUGGCCGAGG 20 1626 BCL11A-1142 - GCGGCCACCUGGCCGAGGCC 20 1627 BCL11A-1143 - CUGGCCGAGGCCGAGGGCCA 20 1628 BCL11A-1144 - UGGCCGAGGCCGAGGGCCAC 20 1629 BCL11A-1145 - GGGCCACAGGGACACUUGCG 20 1630 BCL11A-1146 - CGACGAAGACUCGGUGGCCG 20 1631 BCL11A-1147 - AAGACUCGGUGGCCGGCGAG 20 1632 BCL11A-1148 - UUAAUGGCCGCGGCUGCUCC 20 1633 BCL11A-1149 - UGGCCGCGGCUGCUCCCCGG 20 1634 BCL11A-1150 - GCUCCCCGGGCGAGUCGGCC 20 1635 BCL11A-1151 - CUCCCCGGGCGAGUCGGCCU 20 1636 BCL11A-1152 - UCCCCGGGCGAGUCGGCCUC 20 1637 BCL11A-1153 - CCCCGGGCGAGUCGGCCUCG 20 1638 BCL11A-1154 - GCCUGUCCAAAAAGCUGCUG 20 1639 BCL11A-1155 - UGCUGGGCAGCCCCAGCUCG 20 1640 BCL11A-1156 - CUUCUCUAAGCGCAUCAAGC 20 1641 BCL11A-1157 - UCUCUAAGCGCAUCAAGCUC 20 1642 BCL11A-1158 - CUAAGCGCAUCAAGCUCGAG 20 1643 BCL11A-1159 - UAAGCGCAUCAAGCUCGAGA 20 1644 BCL11A-1160 - CCCCGGCCGCGAUGCCCAAC 20 1645 BCL11A-1161 - CCCGGCCGCGAUGCCCAACA 20 1646 BCL11A-1162 - CGGCCGCGAUGCCCAACACG 20 1647 BCL11A-1163 - CAAAGAUCCCUUCCUUAGCU 20 1648 BCL11A-1164 - AAAGAUCCCUUCCUUAGCUU 20 1649 BCL11A-1165 - AAUCGCCUUUUGCCUCCUCG 20 1650 BCL11A-1166 - AUCGCCUUUUGCCUCCUCGU 20 1651 BCL11A-1167 - CCUCCUCGUCGGAGCACUCC 20 1652 BCL11A-1168 - CUCCUCGUCGGAGCACUCCU 20 1653 BCL11A-1169 - CCUCGUCGGAGCACUCCUCG 20 1654 BCL11A-1170 - GUCGGAGCACUCCUCGGAGA 20 1655 BCL11A-1171 - UCGGAGCACUCCUCGGAGAA 20 1656 BCL11A-1172 - CGGAGCACUCCUCGGAGAAC 20 1657 BCL11A-1173 - UUUGCGCUUCUCCACACCGC 20 1658 BCL11A-1174 - UUGCGCUUCUCCACACCGCC 20 1659 BCL11A-1175 - UGCGCUUCUCCACACCGCCC 20 1660 BCL11A-1176 - GCGCUUCUCCACACCGCCCG 20 1661 BCL11A-1177 - UCUCCACACCGCCCGGGGAG 20 1662 BCL11A-1178 - CACACCGCCCGGGGAGCUGG 20 1663 BCL11A-1179 - ACACCGCCCGGGGAGCUGGA 20 1664 BCL11A-1180 - ACCGCCCGGGGAGCUGGACG 20 1665 BCL11A-1181 - CCGCCCGGGGAGCUGGACGG 20 1666 BCL11A-1182 - GGGAGCUGGACGGAGGGAUC 20 1667 BCL11A-1183 - GGAGCUGGACGGAGGGAUCU 20 1668 BCL11A-1184 - GGAUCUCGGGGCGCAGCGGC 20 1669 BCL11A-1185 - GAUCUCGGGGCGCAGCGGCA 20 1670 BCL11A-1186 - AUCUCGGGGCGCAGCGGCAC 20 1671 BCL11A-1187 - GGGGCGCAGCGGCACGGGAA 20 1672 BCL11A-1188 - GGGCGCAGCGGCACGGGAAG 20 1673 BCL11A-1189 - GCGCAGCGGCACGGGAAGUG 20 1674 BCL11A-1190 - CGCAGCGGCACGGGAAGUGG 20 1675 BCL11A-1191 - GCAGCGGCACGGGAAGUGGA 20 1676 BCL11A-1192 - GCACGCCCCAUAUUAGUGGU 20 1677 BCL11A-1193 - CCCAUAUUAGUGGUCCGGGC 20 1678 BCL11A-1194 - CCCGGGCAGGCCCAGCUCAA 20 1679 BCL11A-1195 - CGGGCAGGCCCAGCUCAAAA 20 1680 BCL11A-1196 - UUCUCUUGCAACACGCA 17 1681 BCL11A-1197 - ACACGCACAGAACACUC 17 1682 BCL11A-1198 - CAGAACACUCAUGGAUU 17 1683 BCL11A-1199 - UGGAUUAAGAAUCUACU 17 1684 BCL11A-1200 - AAGAAUCUACUUAGAAA 17 1685 BCL11A-1201 - CUACUUAGAAAGCGAAC 17 1686 BCL11A-1202 - UACUUAGAAAGCGAACA 17 1687 BCL11A-1203 - GGAAGUCCCCUGACCCC 17 1688 BCL11A-1204 - GCGGGUUGGUAUCCCUU 17 1689 BCL11A-1205 - CCCUUCAGGACUAGGUG 17 1690 BCL11A-1206 - UUCCCAGCCACCUCUCC 17 1691 BCL11A-1207 - UCCCAGCCACCUCUCCA 17 1692 BCL11A-1208 - AACCCCUUUAACCUGCU 17 1693 BCL11A-1209 - UAACCUGCUAAGAAUAC 17 1694 BCL11A-1210 - GAAUACCAGGAUCAGUA 17 1695 BCL11A-1211 - AUACCAGGAUCAGUAUC 17 1696 BCL11A-1212 - ACCAGGAUCAGUAUCGA 17 1697 BCL11A-1213 - AGAGGCUUCCGGCCUGG 17 1698 BCL11A-1214 - GGCUUCCGGCCUGGCAG 17 1699 BCL11A-1215 - CCCUGUUUAGUCCACCA 17 1700 BCL11A-1216 - CACCACCGAGACAUCAC 17 1701 BCL11A-1217 - CUUGGACCCCCACCGCA 17 1702 BCL11A-1218 - CCCACCGCAUAGAGCGC 17 1703 BCL11A-1219 - CCACCGCAUAGAGCGCC 17 1704 BCL11A-1220 - CACCGCAUAGAGCGCCU 17 1705 BCL11A-1221 - GCAUAGAGCGCCUGGGG 17 1706 BCL11A-1222 - CAUAGAGCGCCUGGGGG 17 1707 BCL11A-1223 - AGAGCGCCUGGGGGCGG 17 1708 BCL11A-1224 - CCCUGGCCACCCAUCAC 17 1709 BCL11A-1225 - CACCCGAGUGCCUUUGA 17 1710 BCL11A-1226 - UUGACAGGGUGCUGCGG 17 1711 BCL11A-1227 - GGUUGAAUCCAAUGGCU 17 1712 BCL11A-1228 - GUUGAAUCCAAUGGCUA 17 1713 BCL11A-1229 - CUAUGGAGCCUCCCGCC 17 1714 BCL11A-1230 - CCCGCCAUGGAUUUCUC 17 1715 BCL11A-1231 - CCGCCAUGGAUUUCUCU 17 1716 BCL11A-1232 - GAUUUCUCUAGGAGACU 17 1717 BCL11A-1233 - UUUCUCUAGGAGACUUA 17 1718 BCL11A-1234 - GAGACUUAGAGAGCUGG 17 1719 BCL11A-1235 - AGACUUAGAGAGCUGGC 17 1720 BCL11A-1236 - GACUUAGAGAGCUGGCA 17 1721 BCL11A-1237 - GGUCAAGUCCAAGUCAU 17 1722 BCL11A-1238 - GCAAGACGUUCAAAUUU 17 1723 BCL11A-1239 - UGCACCGGCGCAGCCAC 17 1724 BCL11A-1240 - CCGGCGCAGCCACACGG 17 1725 BCL11A-1241 - GGCGCAGCCACACGGGC 17 1726 BCL11A-1242 - GCACCCAGGCCAGCAAG 17 1727 BCL11A-1243 - GCAAGCUGAAGCGCCAC 17 1728 BCL11A-1244 - UCUCCACCGCCAGCUCC 17 1729 BCL11A-1245 - CUCCACCGCCAGCUCCC 17 1730 BCL11A-1246 - CCGGCACCAGCGACUUG 17 1731 BCL11A-1247 - CCGUGGUGGCCAAGUUC 17 1732 BCL11A-1248 - GGUGGCCAAGUUCAAGA 17 1733 BCL11A-1249 - UGGCCAAGUUCAAGAGC 17 1734 BCL11A-1250 - ACGACCCCAACCUGAUC 17 1735 BCL11A-1251 - CGACCCCAACCUGAUCC 17 1736 BCL11A-1252 - ACCCCAACCUGAUCCCG 17 1737 BCL11A-1253 - CAACCUGAUCCCGGAGA 17 1738 BCL11A-1254 - AACCUGAUCCCGGAGAA 17 1739 BCL11A-1255 - ACCUGAUCCCGGAGAAC 17 1740 BCL11A-1256 - GAUCCCGGAGAACGGGG 17 1741 BCL11A-1257 - UCCCGGAGAACGGGGAC 17 1742 BCL11A-1258 - CCCGGAGAACGGGGACG 17 1743 BCL11A-1259 - CGGAGAACGGGGACGAG 17 1744 BCL11A-1260 - GGAGAACGGGGACGAGG 17 1745 BCL11A-1261 - GAACGGGGACGAGGAGG 17 1746 BCL11A-1262 - ACGGGGACGAGGAGGAA 17 1747 BCL11A-1263 - CGGGGACGAGGAGGAAG 17 1748 BCL11A-1264 - GGGACGAGGAGGAAGAG 17 1749 BCL11A-1265 - GGAGGAAGAGGAGGACG 17 1750 BCL11A-1266 - AGGAAGAGGAGGACGAC 17 1751 BCL11A-1267 - GGAAGAGGAGGACGACG 17 1752 BCL11A-1268 - AGAGGAGGACGACGAGG 17 1753 BCL11A-1269 - AGGAGGACGACGAGGAA 17 1754 BCL11A-1270 - GGAGGACGACGAGGAAG 17 1755 BCL11A-1271 - GGACGACGAGGAAGAGG 17 1756 BCL11A-1272 - CGACGAGGAAGAGGAAG 17 1757 BCL11A-1273 - ACGAGGAAGAGGAAGAA 17 1758 BCL11A-1274 - CGAGGAAGAGGAAGAAG 17 1759 BCL11A-1275 - AGGAAGAGGAAGAAGAG 17 1760 BCL11A-1276 - GGAAGAGGAAGAAGAGG 17 1761 BCL11A-1277 - AGAGGAAGAAGAGGAGG 17 1762 BCL11A-1278 - AGGAAGAAGAGGAGGAA 17 1763 BCL11A-1279 - GGAAGAAGAGGAGGAAG 17 1764 BCL11A-1280 - AAGAAGAGGAGGAAGAG 17 1765 BCL11A-1281 - AGAAGAGGAGGAAGAGG 17 1766 BCL11A-1282 - AAGAGGAGGAAGAGGAG 17 1767 BCL11A-1283 - AGAGGAGGAAGAGGAGG 17 1768 BCL11A-1284 - AGGAGGAAGAGGAGGAG 17 1769 BCL11A-1285 - GGAGGAAGAGGAGGAGG 17 1770 BCL11A-1286 - AGGAGGAGGAGGAGCUG 17 1771 BCL11A-1287 - GGAGGAGGAGGAGCUGA 17 1772 BCL11A-1288 - AGGAGGAGGAGCUGACG 17 1773 BCL11A-1289 - GGAGGAGCUGACGGAGA 17 1774 BCL11A-1290 - AGGAGCUGACGGAGAGC 17 1775 BCL11A-1291 - GAGCUGACGGAGAGCGA 17 1776 BCL11A-1292 - UGACGGAGAGCGAGAGG 17 1777 BCL11A-1293 - GAGGGUGGACUACGGCU 17 1778 BCL11A-1294 - UGGACUACGGCUUCGGG 17 1779 BCL11A-1295 - ACGGCUUCGGGCUGAGC 17 1780 BCL11A-1296 - CGGCUUCGGGCUGAGCC 17 1781 BCL11A-1297 - GGAGGCGGCGCGCCACC 17 1782 BCL11A-1298 - AGGCGGCGCGCCACCAC 17 1783 BCL11A-1299 - CACCACGAGAACAGCUC 17 1784 BCL11A-1300 - ACCACGAGAACAGCUCG 17 1785 BCL11A-1301 - GCUCGCGGGGCGCGGUC 17 1786 BCL11A-1302 - GGGGCGCGGUCGUGGGC 17 1787 BCL11A-1303 - GGUCGUGGGCGUGGGCG 17 1788 BCL11A-1304 - UCGUGGGCGUGGGCGAC 17 1789 BCL11A-1305 - CCCUGCCCGACGUCAUG 17 1790 BCL11A-1306 - CUCCAUGCAGCACUUCA 17 1791 BCL11A-1307 - AGGCCUUCCACCAGGUC 17 1792 BCL11A-1308 - CUUCCACCAGGUCCUGG 17 1793 BCL11A-1309 - UCCACCAGGUCCUGGGC 17 1794 BCL11A-1310 - UAAGCGCGGCCACCUGG 17 1795 BCL11A-1311 - CGGCCACCUGGCCGAGG 17 1796 BCL11A-1312 - GCCACCUGGCCGAGGCC 17 1797 BCL11A-1313 - GCCGAGGCCGAGGGCCA 17 1798 BCL11A-1314 - CCGAGGCCGAGGGCCAC 17 1799 BCL11A-1315 - CCACAGGGACACUUGCG 17 1800 BCL11A-1316 - CGAAGACUCGGUGGCCG 17 1801 BCL11A-1317 - ACUCGGUGGCCGGCGAG 17 1802 BCL11A-1318 - AUGGCCGCGGCUGCUCC 17 1803 BCL11A-1319 - CCGCGGCUGCUCCCCGG 17 1804 BCL11A-1320 - CCCCGGGCGAGUCGGCC 17 1805 BCL11A-1321 - CCCGGGCGAGUCGGCCU 17 1806 BCL11A-1322 - CCGGGCGAGUCGGCCUC 17 1807 BCL11A-1323 - CGGGCGAGUCGGCCUCG 17 1808 BCL11A-1324 - UGUCCAAAAAGCUGCUG 17 1809 BCL11A-1325 - UGGGCAGCCCCAGCUCG 17 1810 BCL11A-1326 - CUCUAAGCGCAUCAAGC 17 1811 BCL11A-1327 - CUAAGCGCAUCAAGCUC 17 1812 BCL11A-1328 - AGCGCAUCAAGCUCGAG 17 1813 BCL11A-1329 - GCGCAUCAAGCUCGAGA 17 1814 BCL11A-1330 - CGGCCGCGAUGCCCAAC 17 1815 BCL11A-1331 - GGCCGCGAUGCCCAACA 17 1816 BCL11A-1332 - CCGCGAUGCCCAACACG 17 1817 BCL11A-1333 - AGAUCCCUUCCUUAGCU 17 1818 BCL11A-1334 - GAUCCCUUCCUUAGCUU 17 1819 BCL11A-1335 - CGCCUUUUGCCUCCUCG 17 1820 BCL11A-1336 - GCCUUUUGCCUCCUCGU 17 1821 BCL11A-1337 - CCUCGUCGGAGCACUCC 17 1822 BCL11A-1338 - CUCGUCGGAGCACUCCU 17 1823 BCL11A-1339 - CGUCGGAGCACUCCUCG 17 1824 BCL11A-1340 - GGAGCACUCCUCGGAGA 17 1825 BCL11A-1341 - GAGCACUCCUCGGAGAA 17 1826 BCL11A-1342 - AGCACUCCUCGGAGAAC 17 1827 BCL11A-1343 - GCGCUUCUCCACACCGC 17 1828 BCL11A-1344 - CGCUUCUCCACACCGCC 17 1829 BCL11A-1345 - GCUUCUCCACACCGCCC 17 1830 BCL11A-1346 - CUUCUCCACACCGCCCG 17 1831 BCL11A-1347 - CCACACCGCCCGGGGAG 17 1832 BCL11A-1348 - ACCGCCCGGGGAGCUGG 17 1833 BCL11A-1349 - CCGCCCGGGGAGCUGGA 17 1834 BCL11A-1350 - GCCCGGGGAGCUGGACG 17 1835 BCL11A-1351 - CCCGGGGAGCUGGACGG 17 1836 BCL11A-1352 - AGCUGGACGGAGGGAUC 17 1837 BCL11A-1353 - GCUGGACGGAGGGAUCU 17 1838 BCL11A-1354 - UCUCGGGGCGCAGCGGC 17 1839 BCL11A-1355 - CUCGGGGCGCAGCGGCA 17 1840 BCL11A-1356 - UCGGGGCGCAGCGGCAC 17 1841 BCL11A-1357 - GCGCAGCGGCACGGGAA 17 1842 BCL11A-1358 - CGCAGCGGCACGGGAAG 17 1843 BCL11A-1359 - CAGCGGCACGGGAAGUG 17 1844 BCL11A-1360 - AGCGGCACGGGAAGUGG 17 1845 BCL11A-1361 - GCGGCACGGGAAGUGGA 17 1846 BCL11A-1362 - CGCCCCAUAUUAGUGGU 17 1847 BCL11A-1363 - AUAUUAGUGGUCCGGGC 17 1848 BCL11A-1364 - GGGCAGGCCCAGCUCAA 17 1849 BCL11A-1365 - GCAGGCCCAGCUCAAAA 17 1850 BCL11A-1366 + AAGUUGUACAUGUGUAGCUG 20 1851 BCL11A-1367 + GCAAGAGAAACCAUGCACUG 20 1852 BCL11A-1368 + GUGUUCUGUGCGUGUUGCAA 20 1853 BCL11A-1369 + GAGUGUUCUGUGCGUGUUGC 20 1854 BCL11A-1370 + UCUAAGUAGAUUCUUAAUCC 20 1855 BCL11A-1371 + GAUACCAACCCGCGGGGUCA 20 1856 BCL11A-1372 + GGAUACCAACCCGCGGGGUC 20 1857 BCL11A-1373 + GGGAUACCAACCCGCGGGGU 20 1858 BCL11A-1374 + CCUGAAGGGAUACCAACCCG 20 1859 BCL11A-1375 + UCCUGAAGGGAUACCAACCC 20 1860 BCL11A-1376 + CAUUCUGCACCUAGUCCUGA 20 1861 BCL11A-1377 + ACAUUCUGCACCUAGUCCUG 20 1862 BCL11A-1378 + AGGACAUUCUGCACCUAGUC 20 1863 BCL11A-1379 + CCCAUGGAGAGGUGGCUGGG 20 1864 BCL11A-1380 + AAUCCCAUGGAGAGGUGGCU 20 1865 BCL11A-1381 + GAAUCCCAUGGAGAGGUGGC 20 1866 BCL11A-1382 + UGAAUCCCAUGGAGAGGUGG 20 1867 BCL11A-1383 + UCUGCAAUAUGAAUCCCAUG 20 1868 BCL11A-1384 + UGUCUGCAAUAUGAAUCCCA 20 1869 BCL11A-1385 + UUGUCUGCAAUAUGAAUCCC 20 1870 BCL11A-1386 + AAGGGGUUAUUGUCUGCAAU 20 1871 BCL11A-1387 + UGGUAUUCUUAGCAGGUUAA 20 1872 BCL11A-1388 + CUGGUAUUCUUAGCAGGUUA 20 1873 BCL11A-1389 + AAAGCGCCCUUCUGCCAGGC 20 1874 BCL11A-1390 + GAAAGCGCCCUUCUGCCAGG 20 1875 BCL11A-1391 + CUAAACAGGGGGGGAGUGGG 20 1876 BCL11A-1392 + ACUAAACAGGGGGGGAGUGG 20 1877 BCL11A-1393 + GUGGACUAAACAGGGGGGGA 20 1878 BCL11A-1394 + GGUGGUGGACUAAACAGGGG 20 1879 BCL11A-1395 + CGGUGGUGGACUAAACAGGG 20 1880 BCL11A-1396 + UCGGUGGUGGACUAAACAGG 20 1881 BCL11A-1397 + CUCGGUGGUGGACUAAACAG 20 1882 BCL11A-1398 + UCUCGGUGGUGGACUAAACA 20 1883 BCL11A-1399 + GUCUCGGUGGUGGACUAAAC 20 1884 BCL11A-1400 + UGUCUCGGUGGUGGACUAAA 20 1885 BCL11A-1401 + GUCCAAGUGAUGUCUCGGUG 20 1886 BCL11A-1402 + CCCCAGGCGCUCUAUGCGGU 20 1887 BCL11A-1403 + CCCCCAGGCGCUCUAUGCGG 20 1888 BCL11A-1404 + GCCCCCAGGCGCUCUAUGCG 20 1889 BCL11A-1405 + GCACUCGGGUGAUGGGUGGC 20 1890 BCL11A-1406 + CUGUCAAAGGCACUCGGGUG 20 1891 BCL11A-1407 + CAGCACCCUGUCAAAGGCAC 20 1892 BCL11A-1408 + GGCGGGAGGCUCCAUAGCCA 20 1893 BCL11A-1409 + CUCCUAGAGAAAUCCAUGGC 20 1894 BCL11A-1410 + UCUCCUAGAGAAAUCCAUGG 20 1895 BCL11A-1411 + GUCUCCUAGAGAAAUCCAUG 20 1896 BCL11A-1412 + CCAGCUCUCUAAGUCUCCUA 20 1897 BCL11A-1413 + UGCCAGCUCUCUAAGUCUCC 20 1898 BCL11A-1414 + GGGCCGGCCUGGGGACAGCG 20 1899 BCL11A-1415 + GCAUAGGGCUGGGCCGGCCU 20 1900 BCL11A-1416 + UGCAUAGGGCUGGGCCGGCC 20 1901 BCL11A-1417 + UUGCAUAGGGCUGGGCCGGC 20 1902 BCL11A-1418 + GCAGUAACCUUUGCAUAGGG 20 1903 BCL11A-1419 + UGGUUGCAGUAACCUUUGCA 20 1904 BCL11A-1420 + AGGGCGGCUUGCUACCUGGC 20 1905 BCL11A-1421 + AAGGGCGGCUUGCUACCUGG 20 1906 BCL11A-1422 + GGAGGGGGGGCGUCGCCAGG 20 1907 BCL11A-1423 + GAGGGAGGGGGGGCGUCGCC 20 1908 BCL11A-1424 + GGAGGGAGGGGGGGCGUCGC 20 1909 BCL11A-1425 + CGGAUUGCAGAGGAGGGAGG 20 1910 BCL11A-1426 + GCGGAUUGCAGAGGAGGGAG 20 1911 BCL11A-1427 + GGCGGAUUGCAGAGGAGGGA 20 1912 BCL11A-1428 + GGGCGGAUUGCAGAGGAGGG 20 1913 BCL11A-1429 + GGGGCGGAUUGCAGAGGAGG 20 1914 BCL11A-1430 + GAGGGGCGGAUUGCAGAGGA 20 1915 BCL11A-1431 + GGAGGGGCGGAUUGCAGAGG 20 1916 BCL11A-1432 + AGGAGGGGCGGAUUGCAGAG 20 1917 BCL11A-1433 + GGAGGAGGGGCGGAUUGCAG 20 1918 BCL11A-1434 + GGGAGGAGGGGCGGAUUGCA 20 1919 BCL11A-1435 + GAGGGAGGAGGGGCGGAUUG 20 1920 BCL11A-1436 + GGGGCUGGGAGGGAGGAGGG 20 1921 BCL11A-1437 + ACCGGGGGCUGGGAGGGAGG 20 1922 BCL11A-1438 + GACCGGGGGCUGGGAGGGAG 20 1923 BCL11A-1439 + UUGACCGGGGGCUGGGAGGG 20 1924 BCL11A-1440 + CUUGACCGGGGGCUGGGAGG 20 1925 BCL11A-1441 + GACUUGACCGGGGGCUGGGA 20 1926 BCL11A-1442 + GGACUUGACCGGGGGCUGGG 20 1927 BCL11A-1443 + UGGACUUGACCGGGGGCUGG 20 1928 BCL11A-1444 + CUUGGACUUGACCGGGGGCU 20 1929 BCL11A-1445 + ACUUGGACUUGACCGGGGGC 20 1930 BCL11A-1446 + GACUUGGACUUGACCGGGGG 20 1931 BCL11A-1447 + CGCAUGACUUGGACUUGACC 20 1932 BCL11A-1448 + UCGCAUGACUUGGACUUGAC 20 1933 BCL11A-1449 + CUCGCAUGACUUGGACUUGA 20 1934 BCL11A-1450 + UGCCGCAGAACUCGCAUGAC 20 1935 BCL11A-1451 + GAAAUUUGAACGUCUUGCCG 20 1936 BCL11A-1452 + CCACCAGGUUGCUCUGAAAU 20 1937 BCL11A-1453 + CGGUGCACCACCAGGUUGCU 20 1938 BCL11A-1454 + GGUCGCACAGGUUGCACUUG 20 1939 BCL11A-1455 + UGGCGCUUCAGCUUGCUGGC 20 1940 BCL11A-1456 + CGUCGGACUUGACCGUCAUG 20 1941 BCL11A-1457 + UCGUCGGACUUGACCGUCAU 20 1942 BCL11A-1458 + GUCGUCGGACUUGACCGUCA 20 1943 BCL11A-1459 + CGUCGUCGGACUUGACCGUC 20 1944 BCL11A-1460 + UGGCGGUGGAGAGACCGUCG 20 1945 BCL11A-1461 + GUUCCGGGGAGCUGGCGGUG 20 1946 BCL11A-1462 + GGGUUCCGGGGAGCUGGCGG 20 1947 BCL11A-1463 + CGGGUUCCGGGGAGCUGGCG 20 1948 BCL11A-1464 + GUCGCUGGUGCCGGGUUCCG 20 1949 BCL11A-1465 + AGUCGCUGGUGCCGGGUUCC 20 1950 BCL11A-1466 + AAGUCGCUGGUGCCGGGUUC 20 1951 BCL11A-1467 + CAAGUCGCUGGUGCCGGGUU 20 1952 BCL11A-1468 + UGCCCACCAAGUCGCUGGUG 20 1953 BCL11A-1469 + UGAACUUGGCCACCACGGAC 20 1954 BCL11A-1470 + CGCUCUUGAACUUGGCCACC 20 1955 BCL11A-1471 + GGUUGGGGUCGUUCUCGCUC 20 1956 BCL11A-1472 + CCCGUUCUCCGGGAUCAGGU 20 1957 BCL11A-1473 + CCCCGUUCUCCGGGAUCAGG 20 1958 BCL11A-1474 + UCCUCCUCGUCCCCGUUCUC 20 1959 BCL11A-1475 + UUCCUCCUCGUCCCCGUUCU 20 1960 BCL11A-1476 + GCGCCGCCUCCAGGCUCAGC 20 1961 BCL11A-1477 + CACGCCCACGACCGCGCCCC 20 1962 BCL11A-1478 + AUGCCCUGCAUGACGUCGGG 20 1963 BCL11A-1479 + GCACCAUGCCCUGCAUGACG 20 1964 BCL11A-1480 + CGCUGAAGUGCUGCAUGGAG 20 1965 BCL11A-1481 + GGCCUCGCUGAAGUGCUGCA 20 1966 BCL11A-1482 + AGGCCUCGCUGAAGUGCUGC 20 1967 BCL11A-1483 + GGACCUGGUGGAAGGCCUCG 20 1968 BCL11A-1484 + GCUUCUCGCCCAGGACCUGG 20 1969 BCL11A-1485 + UGCUUCUCGCCCAGGACCUG 20 1970 BCL11A-1486 + CCGCGCUUAUGCUUCUCGCC 20 1971 BCL11A-1487 + GCGGUCCGACUCGCCGGCCA 20 1972 BCL11A-1488 + CCCCGAGGCCGACUCGCCCG 20 1973 BCL11A-1489 + CCCCCGAGGCCGACUCGCCC 20 1974 BCL11A-1490 + CCCCCCGAGGCCGACUCGCC 20 1975 BCL11A-1491 + GCCCCCCGAGGCCGACUCGC 20 1976 BCL11A-1492 + CAGCUUUUUGGACAGGCCCC 20 1977 BCL11A-1493 + GGCUGCCCAGCAGCAGCUUU 20 1978 BCL11A-1494 + AGAGAAGGGGCUCAGCGAGC 20 1979 BCL11A-1495 + UAGAGAAGGGGCUCAGCGAG 20 1980 BCL11A-1496 + GCGCUUAGAGAAGGGGCUCA 20 1981 BCL11A-1497 + GAGCUUGAUGCGCUUAGAGA 20 1982 BCL11A-1498 + CGAGCUUGAUGCGCUUAGAG 20 1983 BCL11A-1499 + UCUCGAGCUUGAUGCGCUUA 20 1984 BCL11A-1500 + CUUCUCGAGCUUGAUGCGCU 20 1985 BCL11A-1501 + GGGGCAGGUCGAACUCCUUC 20 1986 BCL11A-1502 + GCAUCGCGGCCGGGGGCAGG 20 1987 BCL11A-1503 + CCGUGUUGGGCAUCGCGGCC 20 1988 BCL11A-1504 + UCCGUGUUGGGCAUCGCGGC 20 1989 BCL11A-1505 + CUCCGUGUUGGGCAUCGCGG 20 1990 BCL11A-1506 + GCGAGUACACGUUCUCCGUG 20 1991 BCL11A-1507 + CGCGUAGCCGGCGAGCCACU 20 1992 BCL11A-1508 + GCCUGGAGGCCGCGUAGCCG 20 1993 BCL11A-1509 + GAAGGGAUCUUUGAGCUGCC 20 1994 BCL11A-1510 + GGAAGGGAUCUUUGAGCUGC 20 1995 BCL11A-1511 + CGAAGCUAAGGAAGGGAUCU 20 1996 BCL11A-1512 + GGAGUCUCCGAAGCUAAGGA 20 1997 BCL11A-1513 + UGGAGUCUCCGAAGCUAAGG 20 1998 BCL11A-1514 + GUCUGGAGUCUCCGAAGCUA 20 1999 BCL11A-1515 + UGUCUGGAGUCUCCGAAGCU 20 2000 BCL11A-1516 + AAGGCGAUUGUCUGGAGUCU 20 2001 BCL11A-1517 + GGAGGCAAAAGGCGAUUGUC 20 2002 BCL11A-1518 + AGGAGGCAAAAGGCGAUUGU 20 2003 BCL11A-1519 + CUCCGAGGAGUGCUCCGACG 20 2004 BCL11A-1520 + UCUCCGAGGAGUGCUCCGAC 20 2005 BCL11A-1521 + GUUCUCCGAGGAGUGCUCCG 20 2006 BCL11A-1522 + GCGCAAACUCCCGUUCUCCG 20 2007 BCL11A-1523 + AGCGCAAACUCCCGUUCUCC 20 2008 BCL11A-1524 + GAAGCGCAAACUCCCGUUCU 20 2009 BCL11A-1525 + CCAGCUCCCCGGGCGGUGUG 20 2010 BCL11A-1526 + GUCCAGCUCCCCGGGCGGUG 20 2011 BCL11A-1527 + CGUCCAGCUCCCCGGGCGGU 20 2012 BCL11A-1528 + AGAUCCCUCCGUCCAGCUCC 20 2013 BCL11A-1529 + ACUUCCCGUGCCGCUGCGCC 20 2014 BCL11A-1530 + CCGGGCCCGGACCACUAAUA 20 2015 BCL11A-1531 + CCCGGGCCCGGACCACUAAU 20 2016 BCL11A-1532 + UGAGCUGGGCCUGCCCGGGC 20 2017 BCL11A-1533 + CUCUUUUGAGCUGGGCCUGC 20 2018 BCL11A-1534 + UGCGUCUGCCCUCUUUUGAG 20 2019 BCL11A-1535 + GUCGCUGCGUCUGCCCUCUU 20 2020 BCL11A-1536 + UUGUACAUGUGUAGCUG 17 2021 BCL11A-1537 + AGAGAAACCAUGCACUG 17 2022 BCL11A-1538 + UUCUGUGCGUGUUGCAA 17 2023 BCL11A-1539 + UGUUCUGUGCGUGUUGC 17 2024 BCL11A-1540 + AAGUAGAUUCUUAAUCC 17 2025 BCL11A-1541 + ACCAACCCGCGGGGUCA 17 2026 BCL11A-1542 + UACCAACCCGCGGGGUC 17 2027 BCL11A-1543 + AUACCAACCCGCGGGGU 17 2028 BCL11A-1544 + GAAGGGAUACCAACCCG 17 2029 BCL11A-1545 + UGAAGGGAUACCAACCC 17 2030 BCL11A-1546 + UCUGCACCUAGUCCUGA 17 2031 BCL11A-1547 + UUCUGCACCUAGUCCUG 17 2032 BCL11A-1548 + ACAUUCUGCACCUAGUC 17 2033 BCL11A-1549 + AUGGAGAGGUGGCUGGG 17 2034 BCL11A-1550 + CCCAUGGAGAGGUGGCU 17 2035 BCL11A-1551 + UCCCAUGGAGAGGUGGC 17 2036 BCL11A-1552 + AUCCCAUGGAGAGGUGG 17 2037 BCL11A-1553 + GCAAUAUGAAUCCCAUG 17 2038 BCL11A-1554 + CUGCAAUAUGAAUCCCA 17 2039 BCL11A-1555 + UCUGCAAUAUGAAUCCC 17 2040 BCL11A-1556 + GGGUUAUUGUCUGCAAU 17 2041 BCL11A-1557 + UAUUCUUAGCAGGUUAA 17 2042 BCL11A-1558 + GUAUUCUUAGCAGGUUA 17 2043 BCL11A-1559 + GCGCCCUUCUGCCAGGC 17 2044 BCL11A-1560 + AGCGCCCUUCUGCCAGG 17 2045 BCL11A-1561 + AACAGGGGGGGAGUGGG 17 2046 BCL11A-1562 + AAACAGGGGGGGAGUGG 17 2047 BCL11A-1563 + GACUAAACAGGGGGGGA 17 2048 BCL11A-1564 + GGUGGACUAAACAGGGG 17 2049 BCL11A-1565 + UGGUGGACUAAACAGGG 17 2050 BCL11A-1566 + GUGGUGGACUAAACAGG 17 2051 BCL11A-1567 + GGUGGUGGACUAAACAG 17 2052 BCL11A-1568 + CGGUGGUGGACUAAACA 17 2053 BCL11A-1569 + UCGGUGGUGGACUAAAC 17 2054 BCL11A-1570 + CUCGGUGGUGGACUAAA 17 2055 BCL11A-1571 + CAAGUGAUGUCUCGGUG 17 2056 BCL11A-1572 + CAGGCGCUCUAUGCGGU 17 2057 BCL11A-1573 + CCAGGCGCUCUAUGCGG 17 2058 BCL11A-1574 + CCCAGGCGCUCUAUGCG 17 2059 BCL11A-1575 + CUCGGGUGAUGGGUGGC 17 2060 BCL11A-1576 + UCAAAGGCACUCGGGUG 17 2061 BCL11A-1577 + CACCCUGUCAAAGGCAC 17 2062 BCL11A-1578 + GGGAGGCUCCAUAGCCA 17 2063 BCL11A-1579 + CUAGAGAAAUCCAUGGC 17 2064 BCL11A-1580 + CCUAGAGAAAUCCAUGG 17 2065 BCL11A-1581 + UCCUAGAGAAAUCCAUG 17 2066 BCL11A-1582 + GCUCUCUAAGUCUCCUA 17 2067 BCL11A-1583 + CAGCUCUCUAAGUCUCC 17 2068 BCL11A-1584 + CCGGCCUGGGGACAGCG 17 2069 BCL11A-1585 + UAGGGCUGGGCCGGCCU 17 2070 BCL11A-1586 + AUAGGGCUGGGCCGGCC 17 2071 BCL11A-1587 + CAUAGGGCUGGGCCGGC 17 2072 BCL11A-1588 + GUAACCUUUGCAUAGGG 17 2073 BCL11A-1589 + UUGCAGUAACCUUUGCA 17 2074 BCL11A-1590 + GCGGCUUGCUACCUGGC 17 2075 BCL11A-1591 + GGCGGCUUGCUACCUGG 17 2076 BCL11A-1592 + GGGGGGGCGUCGCCAGG 17 2077 BCL11A-1593 + GGAGGGGGGGCGUCGCC 17 2078 BCL11A-1594 + GGGAGGGGGGGCGUCGC 17 2079 BCL11A-1595 + AUUGCAGAGGAGGGAGG 17 2080 BCL11A-1596 + GAUUGCAGAGGAGGGAG 17 2081 BCL11A-1597 + GGAUUGCAGAGGAGGGA 17 2082 BCL11A-1598 + CGGAUUGCAGAGGAGGG 17 2083 BCL11A-1599 + GCGGAUUGCAGAGGAGG 17 2084 BCL11A-1600 + GGGCGGAUUGCAGAGGA 17 2085 BCL11A-1601 + GGGGCGGAUUGCAGAGG 17 2086 BCL11A-1602 + AGGGGCGGAUUGCAGAG 17 2087 BCL11A-1603 + GGAGGGGCGGAUUGCAG 17 2088 BCL11A-1604 + AGGAGGGGCGGAUUGCA 17 2089 BCL11A-1605 + GGAGGAGGGGCGGAUUG 17 2090 BCL11A-1606 + GCUGGGAGGGAGGAGGG 17 2091 BCL11A-1607 + GGGGGCUGGGAGGGAGG 17 2092 BCL11A-1608 + CGGGGGCUGGGAGGGAG 17 2093 BCL11A-1609 + ACCGGGGGCUGGGAGGG 17 2094 BCL11A-1610 + GACCGGGGGCUGGGAGG 17 2095 BCL11A-1611 + UUGACCGGGGGCUGGGA 17 2096 BCL11A-1612 + CUUGACCGGGGGCUGGG 17 2097 BCL11A-1613 + ACUUGACCGGGGGCUGG 17 2098 BCL11A-1614 + GGACUUGACCGGGGGCU 17 2099 BCL11A-1615 + UGGACUUGACCGGGGGC 17 2100 BCL11A-1616 + UUGGACUUGACCGGGGG 17 2101 BCL11A-1617 + AUGACUUGGACUUGACC 17 2102 BCL11A-1618 + CAUGACUUGGACUUGAC 17 2103 BCL11A-1619 + GCAUGACUUGGACUUGA 17 2104 BCL11A-1620 + CGCAGAACUCGCAUGAC 17 2105 BCL11A-1621 + AUUUGAACGUCUUGCCG 17 2106 BCL11A-1622 + CCAGGUUGCUCUGAAAU 17 2107 BCL11A-1623 + UGCACCACCAGGUUGCU 17 2108 BCL11A-1624 + CGCACAGGUUGCACUUG 17 2109 BCL11A-1625 + CGCUUCAGCUUGCUGGC 17 2110 BCL11A-1626 + CGGACUUGACCGUCAUG 17 2111 BCL11A-1627 + UCGGACUUGACCGUCAU 17 2112 BCL11A-1628 + GUCGGACUUGACCGUCA 17 2113 BCL11A-1629 + CGUCGGACUUGACCGUC 17 2114 BCL11A-1630 + CGGUGGAGAGACCGUCG 17 2115 BCL11A-1631 + CCGGGGAGCUGGCGGUG 17 2116 BCL11A-1632 + UUCCGGGGAGCUGGCGG 17 2117 BCL11A-1633 + GUUCCGGGGAGCUGGCG 17 2118 BCL11A-1634 + GCUGGUGCCGGGUUCCG 17 2119 BCL11A-1635 + CGCUGGUGCCGGGUUCC 17 2120 BCL11A-1636 + UCGCUGGUGCCGGGUUC 17 2121 BCL11A-1637 + GUCGCUGGUGCCGGGUU 17 2122 BCL11A-1638 + CCACCAAGUCGCUGGUG 17 2123 BCL11A-1639 + ACUUGGCCACCACGGAC 17 2124 BCL11A-1640 + UCUUGAACUUGGCCACC 17 2125 BCL11A-1641 + UGGGGUCGUUCUCGCUC 17 2126 BCL11A-1642 + GUUCUCCGGGAUCAGGU 17 2127 BCL11A-1643 + CGUUCUCCGGGAUCAGG 17 2128 BCL11A-1644 + UCCUCGUCCCCGUUCUC 17 2129 BCL11A-1645 + CUCCUCGUCCCCGUUCU 17 2130 BCL11A-1646 + CCGCCUCCAGGCUCAGC 17 2131 BCL11A-1647 + GCCCACGACCGCGCCCC 17 2132 BCL11A-1648 + CCCUGCAUGACGUCGGG 17 2133 BCL11A-1649 + CCAUGCCCUGCAUGACG 17 2134 BCL11A-1650 + UGAAGUGCUGCAUGGAG 17 2135 BCL11A-1651 + CUCGCUGAAGUGCUGCA 17 2136 BCL11A-1652 + CCUCGCUGAAGUGCUGC 17 2137 BCL11A-1653 + CCUGGUGGAAGGCCUCG 17 2138 BCL11A-1654 + UCUCGCCCAGGACCUGG 17 2139 BCL11A-1655 + UUCUCGCCCAGGACCUG 17 2140 BCL11A-1656 + CGCUUAUGCUUCUCGCC 17 2141 BCL11A-1657 + GUCCGACUCGCCGGCCA 17 2142 BCL11A-1658 + CGAGGCCGACUCGCCCG 17 2143 BCL11A-1659 + CCGAGGCCGACUCGCCC 17 2144 BCL11A-1660 + CCCGAGGCCGACUCGCC 17 2145 BCL11A-1661 + CCCCGAGGCCGACUCGC 17 2146 BCL11A-1662 + CUUUUUGGACAGGCCCC 17 2147 BCL11A-1663 + UGCCCAGCAGCAGCUUU 17 2148 BCL11A-1664 + GAAGGGGCUCAGCGAGC 17 2149 BCL11A-1665 + AGAAGGGGCUCAGCGAG 17 2150 BCL11A-1666 + CUUAGAGAAGGGGCUCA 17 2151 BCL11A-1667 + CUUGAUGCGCUUAGAGA 17 2152 BCL11A-1668 + GCUUGAUGCGCUUAGAG 17 2153 BCL11A-1669 + CGAGCUUGAUGCGCUUA 17 2154 BCL11A-1670 + CUCGAGCUUGAUGCGCU 17 2155 BCL11A-1671 + GCAGGUCGAACUCCUUC 17 2156 BCL11A-1672 + UCGCGGCCGGGGGCAGG 17 2157 BCL11A-1673 + UGUUGGGCAUCGCGGCC 17 2158 BCL11A-1674 + GUGUUGGGCAUCGCGGC 17 2159 BCL11A-1675 + CGUGUUGGGCAUCGCGG 17 2160 BCL11A-1676 + AGUACACGUUCUCCGUG 17 2161 BCL11A-1677 + GUAGCCGGCGAGCCACU 17 2162 BCL11A-1678 + UGGAGGCCGCGUAGCCG 17 2163 BCL11A-1679 + GGGAUCUUUGAGCUGCC 17 2164 BCL11A-1680 + AGGGAUCUUUGAGCUGC 17 2165 BCL11A-1681 + AGCUAAGGAAGGGAUCU 17 2166 BCL11A-1682 + GUCUCCGAAGCUAAGGA 17 2167 BCL11A-1683 + AGUCUCCGAAGCUAAGG 17 2168 BCL11A-1684 + UGGAGUCUCCGAAGCUA 17 2169 BCL11A-1685 + CUGGAGUCUCCGAAGCU 17 2170 BCL11A-1686 + GCGAUUGUCUGGAGUCU 17 2171 BCL11A-1687 + GGCAAAAGGCGAUUGUC 17 2172 BCL11A-1688 + AGGCAAAAGGCGAUUGU 17 2173 BCL11A-1689 + CGAGGAGUGCUCCGACG 17 2174 BCL11A-1690 + CCGAGGAGUGCUCCGAC 17 2175 BCL11A-1691 + CUCCGAGGAGUGCUCCG 17 2176 BCL11A-1692 + CAAACUCCCGUUCUCCG 17 2177 BCL11A-1693 + GCAAACUCCCGUUCUCC 17 2178 BCL11A-1694 + GCGCAAACUCCCGUUCU 17 2179 BCL11A-1695 + GCUCCCCGGGCGGUGUG 17 2180 BCL11A-1696 + CAGCUCCCCGGGCGGUG 17 2181 BCL11A-1697 + CCAGCUCCCCGGGCGGU 17 2182 BCL11A-1698 + UCCCUCCGUCCAGCUCC 17 2183 BCL11A-1699 + UCCCGUGCCGCUGCGCC 17 2184 BCL11A-1700 + GGCCCGGACCACUAAUA 17 2185 BCL11A-1701 + GGGCCCGGACCACUAAU 17 2186 BCL11A-1702 + GCUGGGCCUGCCCGGGC 17 2187 BCL11A-1703 + UUUUGAGCUGGGCCUGC 17 2188 BCL11A-1704 + GUCUGCCCUCUUUUGAG 17 2189 BCL11A-1705 + GCUGCGUCUGCCCUCUU 17 2190 BCL11A-1706 - CCCCCAUUCGGCGUAGUACC 20 2191 BCL11A-1707 - CCCAUUCGGCGUAGUACCCA 20 2192 BCL11A-1708 - CUCAAGAUGUGUGGCAGUUU 20 2193 BCL11A-1709 - AGAUGUGUGGCAGUUUUCGG 20 2194 BCL11A-1710 - GAUGUGUGGCAGUUUUCGGA 20 2195 BCL11A-1711 - GGCAGUUUUCGGAUGGAAGC 20 2196 BCL11A-1712 - CAGUUUUCGGAUGGAAGCUC 20 2197 BCL11A-1713 - CCAUUCGGCGUAGUACC 17 2198 BCL11A-1714 - AUUCGGCGUAGUACCCA 17 2199 BCL11A-1715 - AAGAUGUGUGGCAGUUU 17 2200 BCL11A-1716 - UGUGUGGCAGUUUUCGG 17 2201 BCL11A-1717 - GUGUGGCAGUUUUCGGA 17 2202 BCL11A-1718 - AGUUUUCGGAUGGAAGC 17 2203 BCL11A-1719 - UUUUCGGAUGGAAGCUC 17 2204 BCL11A-1720 + ACGCCGAAUGGGGGUGUGUG 20 2205 BCL11A-1721 + ACUACGCCGAAUGGGGGUGU 20 2206 BCL11A-1722 + CUCUGGGUACUACGCCGAAU 20 2207 BCL11A-1723 + UCUCUGGGUACUACGCCGAA 20 2208 BCL11A-1724 + CUCUCUGGGUACUACGCCGA 20 2209 BCL11A-1725 + UGAGCUCUCUGGGUACUACG 20 2210 BCL11A-1726 + UGCCACACAUCUUGAGCUCU 20 2211 BCL11A-1727 + UCCGAAAACUGCCACACAUC 20 2212 BCL11A-1728 + AAGGGCUCUCGAGCUUCCAU 20 2213 BCL11A-1729 + CCGAAUGGGGGUGUGUG 17 2214 BCL11A-1730 + ACGCCGAAUGGGGGUGU 17 2215 BCL11A-1731 + UGGGUACUACGCCGAAU 17 2216 BCL11A-1732 + CUGGGUACUACGCCGAA 17 2217 BCL11A-1733 + UCUGGGUACUACGCCGA 17 2218 BCL11A-1734 + GCUCUCUGGGUACUACG 17 2219 BCL11A-1735 + CACACAUCUUGAGCUCU 17 2220 BCL11A-1736 + GAAAACUGCCACACAUC 17 2221 BCL11A-1737 + GGCUCUCGAGCUUCCAU 17 2222

Table 2F provides exemplary targeting domains for knocking out the BCL11A gene. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with an N. meningitidis Cas9 molecule that gives double stranded cleavage. Any of the targeting domains in the table can be used with an N. meningitidis Cas9 single-stranded break nucleases (nickases). In an embodiment, dual targeting is used to create two nicks. When selecting gRNAs for use in a nickase pair, one gRNA targets a domain in the complementary strand and the second gRNA targets a domain in the non-complementary strand, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain targeting the same target position.

TABLE 2F N. meningitidis gRNA targets for BCL11A knockout Tar- get gRNA DNA Targeting Site Name Strand Domain Length BCL11A-1738 − AUCCAGGUCACGCCAGAGGA 20 2223 BCL11A-1739 − UGCAACACGCACAGAACACU 20 2224 BCL11A-1740 − UCCUUCCCAGCCACCUCUCC 20 2225 BCL11A-1741 − AUGGCUAUGGAGCCUCCCGC 20 2226 BCL11A-1742 − CAGGUCACGCCAGAGGA 17 2227 BCL11A-1743 − AACACGCACAGAACACU 17 2228 BCL11A-1744 − UUCCCAGCCACCUCUCC 17 2229 BCL11A-1745 − GCUAUGGAGCCUCCCGC 17 2230 BCL11A-1746 + UGAAAAAAGCAUCCAAUCCC 20 2231 BCL11A-1747 + GGAGGUUGGCAUCCAGGUCA 20 2232 BCL11A-1748 + CGCCUGGGAUGAGUGCAGAA 20 2233 BCL11A-1749 + UAGAAAGCGAACACGGAAGU 20 2234 BCL11A-1750 + GGCUAUGGAGCCUCCCGCCA 20 2235 BCL11A-1751 + CCUCCUCCCUCCCAGCCCCC 20 2236 BCL11A-1752 + CCCAUGACGGUCAAGUCCGA 20 2237 BCL11A-1753 + UUUGCCUCCUCGUCGGAGCA 20 2238 BCL11A-1754 + UGAAAAAAGCAUCCAAU 17 2239 BCL11A-1755 + GGAGGUUGGCAUCCAGG 17 2240 BCL11A-1756 + CGCCUGGGAUGAGUGCA 17 2241 BCL11A-1757 + UAGAAAGCGAACACGGA 17 2242 BCL11A-1758 + GGCUAUGGAGCCUCCCG 17 2243 BCL11A-1759 + CCUCCUCCCUCCCAGCC 17 2244 BCL11A-1760 + CCCAUGACGGUCAAGUC 17 2245 BCL11A-1761 + UUUGCCUCCUCGUCGGA 17 2246

Table 3A provides exemplary targeting domains for repressing (i.e., knocking down or decreasing) expression of the BCL11A gene. In an embodiment, the targeting domain is the exact complement of the target domain. Any of the targeting domains in the table can be used with a S. pyogenes eiCas9 molecule to cause a steric block at the promoter region to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a S. pyogenes eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 3A S. pyogenes gRNA targets for BCL11A knockdown Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO BCL11A-1762 − UCUUCUCCUUGCUGCCUCUG 20 2247 BCL11A-1763 − UCCUUGCUGCCUCUGAGGUU 20 2248 BCL11A-1764 − UGCUGCCUCUGAGGUUCGGU 20 2249 BCL11A-1765 − GCUGCCUCUGAGGUUCGGUC 20 2250 BCL11A-1766 − GCCUCUGAGGUUCGGUCGGG 20 2251 BCL11A-1767 − CCUCUGAGGUUCGGUCGGGA 20 2252 BCL11A-1768 − CUCUGAGGUUCGGUCGGGAG 20 2253 BCL11A-1769 − UGAGGUUCGGUCGGGAGGGG 20 2254 BCL11A-1770 − GAGGUUCGGUCGGGAGGGGA 20 2255 BCL11A-1771 − CGGUCGGGAGGGGAGGGCAG 20 2256 BCL11A-1772 − GGGGAGGGCAGCGGCAACCC 20 2257 BCL11A-1773 − GAGGGCAGCGGCAACCCAGG 20 2258 BCL11A-1774 − CAACCCAGGAGGCAGCAGUC 20 2259 BCL11A-1775 − AACCCAGGAGGCAGCAGUCC 20 2260 BCL11A-1776 − CUCCCUCUCCCGCGUGCCCC 20 2261 BCL11A-1777 − CCCCCGGCCGCCUCCUCCCC 20 2262 BCL11A-1778 − CGGCCCUAGCUCCUGCCCUU 20 2263 BCL11A-1779 − CCCUAGCUCCUGCCCUUCGG 20 2264 BCL11A-1780 − UAGCUCCUGCCCUUCGGCGG 20 2265 BCL11A-1781 − CUCCUGCCCUUCGGCGGCGG 20 2266 BCL11A-1782 − CUGCCCUUCGGCGGCGGCGG 20 2267 BCL11A-1783 − CCCUUCGGCGGCGGCGGCGG 20 2268 BCL11A-1784 − UUCGGCGGCGGCGGCGGCGG 20 2269 BCL11A-1785 − CGGCGGCGGCGGCGGCGGCG 20 2270 BCL11A-1786 − GGCGGCGGCGGCGGCGGCGC 20 2271 BCL11A-1787 − GGCGGCGGCGGCGGCGCGGG 20 2272 BCL11A-1788 − GCGGCGGCGGCGGCGCGGGA 20 2273 BCL11A-1789 − GGCGCGGGAGGGCAAGCGCG 20 2274 BCL11A-1790 − GGAGGGCAAGCGCGAGGAGC 20 2275 BCL11A-1791 − GCGCGAGGAGCCGGCACAAA 20 2276 BCL11A-1792 − GGAGCCGGCACAAAAGGCAG 20 2277 BCL11A-1793 − GAGCCGGCACAAAAGGCAGC 20 2278 BCL11A-1794 − GCGGGACAAACACCCACCUC 20 2279 BCL11A-1795 − GACAAACACCCACCUCUGGC 20 2280 BCL11A-1796 − CCACCUCUGGCCGGAACAAA 20 2281 BCL11A-1797 − CCUCUGGCCGGAACAAAAGG 20 2282 BCL11A-1798 − GGAACAAAAGGCGGCAGUGC 20 2283 BCL11A-1799 − GCCGCGUCUCCCGUCCUUCC 20 2284 BCL11A-1800 − UCCCGUCCUUCCCGGUCCCA 20 2285 BCL11A-1801 − CACGGCUCUCCCCGUCGCCG 20 2286 BCL11A-1802 − CGGCCCCUCUCCCGACUCCG 20 2287 BCL11A-1803 − UCUCCCGACUCCGCGGACUC 20 2288 BCL11A-1804 − CUCCGCGGACUCAGGAGCGC 20 2289 BCL11A-1805 − UCCGCGGACUCAGGAGCGCC 20 2290 BCL11A-1806 − CCGCGGACUCAGGAGCGCCG 20 2291 BCL11A-1807 − CGCGGACUCAGGAGCGCCGG 20 2292 BCL11A-1808 − GUGCCACUUUCUCACUAUUG 20 2293 BCL11A-1809 − UGCCACUUUCUCACUAUUGU 20 2294 BCL11A-1810 − GCCACUUUCUCACUAUUGUG 20 2295 BCL11A-1811 − ACACUUGACCGUGAGCGCGC 20 2296 BCL11A-1812 − AGUCUCACCUCUUUUCUCCC 20 2297 BCL11A-1813 − GUCUCACCUCUUUUCUCCCC 20 2298 BCL11A-1814 − CCUACCCCCCCAUUUUCUUA 20 2299 BCL11A-1815 − CCCCAUUUUCUUACGGUGAG 20 2300 BCL11A-1816 − CCCAUUUUCUUACGGUGAGU 20 2301 BCL11A-1817 − CCCCACCAGCUCCCACCCCC 20 2302 BCL11A-1818 − UGUUCAUUAUUUUGCAAAAC 20 2303 BCL11A-1819 − UCAUUAUUUUGCAAAACUGG 20 2304 BCL11A-1820 − CAUUAUUUUGCAAAACUGGC 20 2305 BCL11A-1821 − AUUAUUUUGCAAAACUGGCG 20 2306 BCL11A-1822 − AUUUUGCAAAACUGGCGGGG 20 2307 BCL11A-1823 − UUUUGCAAAACUGGCGGGGC 20 2308 BCL11A-1824 − UUUGCAAAACUGGCGGGGCG 20 2309 BCL11A-1825 − UUGCAAAACUGGCGGGGCGG 20 2310 BCL11A-1826 − UGCAAAACUGGCGGGGCGGG 20 2311 BCL11A-1827 − GCAAAACUGGCGGGGCGGGG 20 2312 BCL11A-1828 − CAAAACUGGCGGGGCGGGGG 20 2313 BCL11A-1829 − CUGGCGGGGCGGGGGGGGAG 20 2314 BCL11A-1830 − UUUCGAAAAGAGAAAUAAAG 20 2315 BCL11A-1831 − CGAAAAGAGAAAUAAAGCGG 20 2316 BCL11A-1832 − AGAGAAAUAAAGCGGCGGAA 20 2317 BCL11A-1833 − GAAAUAAAGCGGCGGAAAGG 20 2318 BCL11A-1834 − AGCGGCGGAAAGGAGGAAAG 20 2319 BCL11A-1835 − GGCGGAAAGGAGGAAAGAGG 20 2320 BCL11A-1836 − UAAAAUUAAAUAAAAUUAAA 20 2321 BCL11A-1837 − CUGUCUCAAAAGUGCAUACA 20 2322 BCL11A-1838 − CAAAAGUGCAUACACGGCAA 20 2323 BCL11A-1839 − UACACGGCAAUGGUUCCAGA 20 2324 BCL11A-1840 − ACACGGCAAUGGUUCCAGAU 20 2325 BCL11A-1841 − CAAUGGUUCCAGAUGGGAUG 20 2326 BCL11A-1842 − AAUGGUUCCAGAUGGGAUGA 20 2327 BCL11A-1843 − AUCUCUUUUACCUCGACUCU 20 2328 BCL11A-1844 − UCUUUUACCUCGACUCUCGG 20 2329 BCL11A-1845 − AUAAUUAUUAUUACUAUUAU 20 2330 BCL11A-1846 − UAAUUAUUAUUACUAUUAUU 20 2331 BCL11A-1847 + UAAUAAUCACGAGAGCGCGC 20 2332 BCL11A-1848 + CAGGACUAGAAGCAAAAGCG 20 2333 BCL11A-1849 + AGGACUAGAAGCAAAAGCGA 20 2334 BCL11A-1850 + GGACUAGAAGCAAAAGCGAG 20 2335 BCL11A-1851 + GACUAGAAGCAAAAGCGAGG 20 2336 BCL11A-1852 + AGCAAAAGCGAGGGGGAGAG 20 2337 BCL11A-1853 + GCAAAAGCGAGGGGGAGAGA 20 2338 BCL11A-1854 + CAAAAGCGAGGGGGAGAGAG 20 2339 BCL11A-1855 + AGAAAAACCUCCGAGAGUCG 20 2340 BCL11A-1856 + AGUCGAGGUAAAAGAGAUAA 20 2341 BCL11A-1857 + GUCGAGGUAAAAGAGAUAAA 20 2342 BCL11A-1858 + UCGAGGUAAAAGAGAUAAAG 20 2343 BCL11A-1859 + CGAGGUAAAAGAGAUAAAGG 20 2344 BCL11A-1860 + GAAAAAACCCUCAUCCCAUC 20 2345 BCL11A-1861 + CUUUAUUUCUCUUUUCGAAA 20 2346 BCL11A-1862 + CAAAAUAAUGAACAAUGCUA 20 2347 BCL11A-1863 + GAACAACUCACAUGCAAACC 20 2348 BCL11A-1864 + AACAACUCACAUGCAAACCU 20 2349 BCL11A-1865 + ACAACUCACAUGCAAACCUG 20 2350 BCL11A-1866 + CAACUCACAUGCAAACCUGG 20 2351 BCL11A-1867 + CUCACAUGCAAACCUGGGGG 20 2352 BCL11A-1868 + UCACAUGCAAACCUGGGGGU 20 2353 BCL11A-1869 + GCAAACCUGGGGGUGGGAGC 20 2354 BCL11A-1870 + AACCUGGGGGUGGGAGCUGG 20 2355 BCL11A-1871 + ACCUGGGGGUGGGAGCUGGU 20 2356 BCL11A-1872 + CCUGGGGGUGGGAGCUGGUG 20 2357 BCL11A-1873 + GGGUGGGAGCUGGUGGGGAA 20 2358 BCL11A-1874 + GGUGGGAGCUGGUGGGGAAA 20 2359 BCL11A-1875 + GGGAGCUGGUGGGGAAAGGG 20 2360 BCL11A-1876 + UCCCACUCACCGUAAGAAAA 20 2361 BCL11A-1877 + CCCACUCACCGUAAGAAAAU 20 2362 BCL11A-1878 + CCACUCACCGUAAGAAAAUG 20 2363 BCL11A-1879 + CACUCACCGUAAGAAAAUGG 20 2364 BCL11A-1880 + ACUCACCGUAAGAAAAUGGG 20 2365 BCL11A-1881 + CUCACCGUAAGAAAAUGGGG 20 2366 BCL11A-1882 + CCGUAAGAAAAUGGGGGGGU 20 2367 BCL11A-1883 + CGUAAGAAAAUGGGGGGGUA 20 2368 BCL11A-1884 + AAGAAAAUGGGGGGGUAGGG 20 2369 BCL11A-1885 + AGAAAAUGGGGGGGUAGGGA 20 2370 BCL11A-1886 + CAAGUCUAAAAAACGAUUCC 20 2371 BCL11A-1887 + AAGUCUAAAAAACGAUUCCC 20 2372 BCL11A-1888 + AGUCUAAAAAACGAUUCCCG 20 2373 BCL11A-1889 + ACGAUUCCCGGGGAGAAAAG 20 2374 BCL11A-1890 + GGGGAGAAAAGAGGUGAGAC 20 2375 BCL11A-1891 + AAAGAGGUGAGACUGGCUUU 20 2376 BCL11A-1892 + UUUGGACACCAGCGCGCUCA 20 2377 BCL11A-1893 + GCUCACGGUCAAGUGUGCAG 20 2378 BCL11A-1894 + CUCACGGUCAAGUGUGCAGC 20 2379 BCL11A-1895 + ACGGUCAAGUGUGCAGCGGG 20 2380 BCL11A-1896 + UCCCCACAAUAGUGAGAAAG 20 2381 BCL11A-1897 + AUAGUGAGAAAGUGGCACUG 20 2382 BCL11A-1898 + GAGAAAGUGGCACUGUGGAA 20 2383 BCL11A-1899 + AGAAAGUGGCACUGUGGAAA 20 2384 BCL11A-1900 + GAAAGUGGCACUGUGGAAAG 20 2385 BCL11A-1901 + GCACUGUGGAAAGGGGCCCC 20 2386 BCL11A-1902 + CCCCGGCGCUCCUGAGUCCG 20 2387 BCL11A-1903 + CGCUCCUGAGUCCGCGGAGU 20 2388 BCL11A-1904 + GCUCCUGAGUCCGCGGAGUC 20 2389 BCL11A-1905 + UGAGUCCGCGGAGUCGGGAG 20 2390 BCL11A-1906 + GAGUCCGCGGAGUCGGGAGA 20 2391 BCL11A-1907 + AGUCCGCGGAGUCGGGAGAG 20 2392 BCL11A-1908 + CGGAGUCGGGAGAGGGGCCG 20 2393 BCL11A-1909 + CGGGAGAGGGGCCGCGGCGA 20 2394 BCL11A-1910 + GGGAGAGGGGCCGCGGCGAC 20 2395 BCL11A-1911 + GGAGAGGGGCCGCGGCGACG 20 2396 BCL11A-1912 + CGCGGCGACGGGGAGAGCCG 20 2397 BCL11A-1913 + GCGGCGACGGGGAGAGCCGU 20 2398 BCL11A-1914 + GACGGGGAGAGCCGUGGGAC 20 2399 BCL11A-1915 + ACGGGGAGAGCCGUGGGACC 20 2400 BCL11A-1916 + GGAGAGCCGUGGGACCGGGA 20 2401 BCL11A-1917 + AGCCGUGGGACCGGGAAGGA 20 2402 BCL11A-1918 + GCCGUGGGACCGGGAAGGAC 20 2403 BCL11A-1919 + ACCGGGAAGGACGGGAGACG 20 2404 BCL11A-1920 + GGAAGGACGGGAGACGCGGC 20 2405 BCL11A-1921 + GGCACUGCCGCCUUUUGUUC 20 2406 BCL11A-1922 + CCGCCUUUUGUUCCGGCCAG 20 2407 BCL11A-1923 + CCUUUUGUUCCGGCCAGAGG 20 2408 BCL11A-1924 + CUUUUGUUCCGGCCAGAGGU 20 2409 BCL11A-1925 + UGUCCCGCUGCCUUUUGUGC 20 2410 BCL11A-1926 + GCCGCCGCCGCCGCCGCCGA 20 2411 BCL11A-1927 + CCGCCGCCGCCGCCGCCGAA 20 2412 BCL11A-1928 + CGCCGCCGCCGCCGAAGGGC 20 2413 BCL11A-1929 + GCCGCCGAAGGGCAGGAGCU 20 2414 BCL11A-1930 + CCGCCGAAGGGCAGGAGCUA 20 2415 BCL11A-1931 + CGAAGGGCAGGAGCUAGGGC 20 2416 BCL11A-1932 + GAAGGGCAGGAGCUAGGGCC 20 2417 BCL11A-1933 + AAGGGCAGGAGCUAGGGCCG 20 2418 BCL11A-1934 + AGGGCAGGAGCUAGGGCCGG 20 2419 BCL11A-1935 + GCAGGAGCUAGGGCCGGGGG 20 2420 BCL11A-1936 + GGAGCUAGGGCCGGGGGAGG 20 2421 BCL11A-1937 + GCUAGGGCCGGGGGAGGAGG 20 2422 BCL11A-1938 + GGGCCGGGGGAGGAGGCGGC 20 2423 BCL11A-1939 + GGCCGGGGGAGGAGGCGGCC 20 2424 BCL11A-1940 + GCCGGGGGAGGAGGCGGCCG 20 2425 BCL11A-1941 + CCGGGGGAGGAGGCGGCCGG 20 2426 BCL11A-1942 + AGGAGGCGGCCGGGGGCACG 20 2427 BCL11A-1943 + GGAGGCGGCCGGGGGCACGC 20 2428 BCL11A-1944 + CGGCCGGGGGCACGCGGGAG 20 2429 BCL11A-1945 + GGCCGGGGGCACGCGGGAGA 20 2430 BCL11A-1946 + CGGGGGCACGCGGGAGAGGG 20 2431 BCL11A-1947 + GGGGGCACGCGGGAGAGGGA 20 2432 BCL11A-1948 + GGCACGCGGGAGAGGGAGGG 20 2433 BCL11A-1949 + GCACGCGGGAGAGGGAGGGA 20 2434 BCL11A-1950 + GGAGAGGGAGGGAGGGAGCC 20 2435 BCL11A-1951 + GAGCCCGGACUGCUGCCUCC 20 2436 BCL11A-1952 + AGCCCGGACUGCUGCCUCCU 20 2437 BCL11A-1953 + CCCUCCCGACCGAACCUCAG 20 2438 BCL11A-1954 + ACCGAACCUCAGAGGCAGCA 20 2439 BCL11A-1955 + AGAGGCAGCAAGGAGAAGAC 20 2440 BCL11A-1956 + AAAAUAAAAUAAAUAAAACA 20 2441 BCL11A-1957 − UCUCCUUGCUGCCUCUG 17 2442 BCL11A-1958 − UUGCUGCCUCUGAGGUU 17 2443 BCL11A-1959 − UGCCUCUGAGGUUCGGU 17 2444 BCL11A-1960 − GCCUCUGAGGUUCGGUC 17 2445 BCL11A-1961 − UCUGAGGUUCGGUCGGG 17 2446 BCL11A-1962 − CUGAGGUUCGGUCGGGA 17 2447 BCL11A-1963 − UGAGGUUCGGUCGGGAG 17 2448 BCL11A-1964 − GGUUCGGUCGGGAGGGG 17 2449 BCL11A-1965 − GUUCGGUCGGGAGGGGA 17 2450 BCL11A-1966 − UCGGGAGGGGAGGGCAG 17 2451 BCL11A-1967 − GAGGGCAGCGGCAACCC 17 2452 BCL11A-1968 − GGCAGCGGCAACCCAGG 17 2453 BCL11A-1969 − CCCAGGAGGCAGCAGUC 17 2454 BCL11A-1970 − CCAGGAGGCAGCAGUCC 17 2455 BCL11A-1971 − CCUCUCCCGCGUGCCCC 17 2456 BCL11A-1972 − CCGGCCGCCUCCUCCCC 17 2457 BCL11A-1973 − CCCUAGCUCCUGCCCUU 17 2458 BCL11A-1974 − UAGCUCCUGCCCUUCGG 17 2459 BCL11A-1975 − CUCCUGCCCUUCGGCGG 17 2460 BCL11A-1976 − CUGCCCUUCGGCGGCGG 17 2461 BCL11A-1977 − CCCUUCGGCGGCGGCGG 17 2462 BCL11A-1978 − UUCGGCGGCGGCGGCGG 17 2463 BCL11A-1979 − GGCGGCGGCGGCGGCGG 17 2464 BCL11A-1980 − CGGCGGCGGCGGCGGCG 17 2465 BCL11A-1981 − GGCGGCGGCGGCGGCGG 17 2466 BCL11A-1982 − GGCGGCGGCGGCGCGGG 17 2467 BCL11A-1983 − GCGGCGGCGGCGCGGGA 17 2468 BCL11A-1984 − GCGGGAGGGCAAGCGCG 17 2469 BCL11A-1985 − GGGCAAGCGCGAGGAGC 17 2470 BCL11A-1986 − CGAGGAGCCGGCACAAA 17 2471 BCL11A-1987 − GCCGGCACAAAAGGCAG 17 2472 BCL11A-1988 − CCGGCACAAAAGGCAGC 17 2473 BCL11A-1989 − GGACAAACACCCACCUC 17 2474 BCL11A-1990 − AAACACCCACCUCUGGC 17 2475 BCL11A-1991 − CCUCUGGCCGGAACAAA 17 2476 BCL11A-1992 − CUGGCCGGAACAAAAGG 17 2477 BCL11A-1993 − ACAAAAGGCGGCAGUGC 17 2478 BCL11A-1994 − GCGUCUCCCGUCCUUCC 17 2479 BCL11A-1995 − CGUCCUUCCCGGUCCCA 17 2480 BCL11A-1996 − GGCUCUCCCCGUCGCCG 17 2481 BCL11A-1997 − CCCCUCUCCCGACUCCG 17 2482 BCL11A-1998 − CCCGACUCCGCGGACUC 17 2483 BCL11A-1999 − CGCGGACUCAGGAGCGC 17 2484 BCL11A-2000 − GCGGACUCAGGAGCGCC 17 2485 BCL11A-2001 − CGGACUCAGGAGCGCCG 17 2486 BCL11A-2002 − GGACUCAGGAGCGCCGG 17 2487 BCL11A-2003 − CCACUUUCUCACUAUUG 17 2488 BCL11A-2004 − CACUUUCUCACUAUUGU 17 2489 BCL11A-2005 − ACUUUCUCACUAUUGUG 17 2490 BCL11A-2006 − CUUGACCGUGAGCGCGC 17 2491 BCL11A-2007 − CUCACCUCUUUUCUCCC 17 2492 BCL11A-2008 − UCACCUCUUUUCUCCCC 17 2493 BCL11A-2009 − ACCCCCCCAUUUUCUUA 17 2494 BCL11A-2010 − CAUUUUCUUACGGUGAG 17 2495 BCL11A-2011 − AUUUUCUUACGGUGAGU 17 2496 BCL11A-2012 − CACCAGCUCCCACCCCC 17 2497 BCL11A-2013 − UCAUUAUUUUGCAAAAC 17 2498 BCL11A-2014 − UUAUUUUGCAAAACUGG 17 2499 BCL11A-2015 − UAUUUUGCAAAACUGGC 17 2500 BCL11A-2016 − AUUUUGCAAAACUGGCG 17 2501 BCL11A-2017 − UUGCAAAACUGGCGGGG 17 2502 BCL11A-2018 − UGCAAAACUGGCGGGGC 17 2503 BCL11A-2019 − GCAAAACUGGCGGGGCG 17 2504 BCL11A-2020 − CAAAACUGGCGGGGCGG 17 2505 BCL11A-2021 − AAAACUGGCGGGGCGGG 17 2506 BCL11A-2022 − AAACUGGCGGGGCGGGG 17 2507 BCL11A-2023 − AACUGGCGGGGCGGGGG 17 2508 BCL11A-2024 − GCGGGGCGGGGGGGGAG 17 2509 BCL11A-2025 − CGAAAAGAGAAAUAAAG 17 2510 BCL11A-2026 − AAAGAGAAAUAAAGCGG 17 2511 BCL11A-2027 − GAAAUAAAGCGGCGGAA 17 2512 BCL11A-2028 − AUAAAGCGGCGGAAAGG 17 2513 BCL11A-2029 − GGCGGAAAGGAGGAAAG 17 2514 BCL11A-2030 − GGAAAGGAGGAAAGAGG 17 2515 BCL11A-2031 − AAUUAAAUAAAAUUAAA 17 2516 BCL11A-2032 − UCUCAAAAGUGCAUACA 17 2517 BCL11A-2033 − AAGUGCAUACACGGCAA 17 2518 BCL11A-2034 − ACGGCAAUGGUUCCAGA 17 2519 BCL11A-2035 − CGGCAAUGGUUCCAGAU 17 2520 BCL11A-2036 − UGGUUCCAGAUGGGAUG 17 2521 BCL11A-2037 − GGUUCCAGAUGGGAUGA 17 2522 BCL11A-2038 − UCUUUUACCUCGACUCU 17 2523 BCL11A-2039 − UUUACCUCGACUCUCGG 17 2524 BCL11A-2040 − AUUAUUAUUACUAUUAU 17 2525 BCL11A-2041 − UUAUUAUUACUAUUAUU 17 2526 BCL11A-2042 + UAAUCACGAGAGCGCGC 17 2527 BCL11A-2043 + GACUAGAAGCAAAAGCG 17 2528 BCL11A-2044 + ACUAGAAGCAAAAGCGA 17 2529 BCL11A-2045 + CUAGAAGCAAAAGCGAG 17 2530 BCL11A-2046 + UAGAAGCAAAAGCGAGG 17 2531 BCL11A-2047 + AAAAGCGAGGGGGAGAG 17 2532 BCL11A-2048 + AAAGCGAGGGGGAGAGA 17 2533 BCL11A-2049 + AAGCGAGGGGGAGAGAG 17 2534 BCL11A-2050 + AAAACCUCCGAGAGUCG 17 2535 BCL11A-2051 + CGAGGUAAAAGAGAUAA 17 2536 BCL11A-2052 + GAGGUAAAAGAGAUAAA 17 2537 BCL11A-2053 + AGGUAAAAGAGAUAAAG 17 2538 BCL11A-2054 + GGUAAAAGAGAUAAAGG 17 2539 BCL11A-2055 + AAAACCCUCAUCCCAUC 17 2540 BCL11A-2056 + UAUUUCUCUUUUCGAAA 17 2541 BCL11A-2057 + AAUAAUGAACAAUGCUA 17 2542 BCL11A-2058 + CAACUCACAUGCAAACC 17 2543 BCL11A-2059 + AACUCACAUGCAAACCU 17 2544 BCL11A-2060 + ACUCACAUGCAAACCUG 17 2545 BCL11A-2061 + CUCACAUGCAAACCUGG 17 2546 BCL11A-2062 + ACAUGCAAACCUGGGGG 17 2547 BCL11A-2063 + CAUGCAAACCUGGGGGU 17 2548 BCL11A-2064 + AACCUGGGGGUGGGAGC 17 2549 BCL11A-2065 + CUGGGGGUGGGAGCUGG 17 2550 BCL11A-2066 + UGGGGGUGGGAGCUGGU 17 2551 BCL11A-2067 + GGGGGUGGGAGCUGGUG 17 2552 BCL11A-2068 + UGGGAGCUGGUGGGGAA 17 2553 BCL11A-2069 + GGGAGCUGGUGGGGAAA 17 2554 BCL11A-2070 + AGCUGGUGGGGAAAGGG 17 2555 BCL11A-2071 + CACUCACCGUAAGAAAA 17 2556 BCL11A-2072 + ACUCACCGUAAGAAAAU 17 2557 BCL11A-2073 + CUCACCGUAAGAAAAUG 17 2558 BCL11A-2074 + UCACCGUAAGAAAAUGG 17 2559 BCL11A-2075 + CACCGUAAGAAAAUGGG 17 2560 BCL11A-2076 + ACCGUAAGAAAAUGGGG 17 2561 BCL11A-2077 + UAAGAAAAUGGGGGGGU 17 2562 BCL11A-2078 + AAGAAAAUGGGGGGGUA 17 2563 BCL11A-2079 + AAAAUGGGGGGGUAGGG 17 2564 BCL11A-2080 + AAAUGGGGGGGUAGGGA 17 2565 BCL11A-2081 + GUCUAAAAAACGAUUCC 17 2566 BCL11A-2082 + UCUAAAAAACGAUUCCC 17 2567 BCL11A-2083 + CUAAAAAACGAUUCCCG 17 2568 BCL11A-2084 + AUUCCCGGGGAGAAAAG 17 2569 BCL11A-2085 + GAGAAAAGAGGUGAGAC 17 2570 BCL11A-2086 + GAGGUGAGACUGGCUUU 17 2571 BCL11A-2087 + GGACACCAGCGCGCUCA 17 2572 BCL11A-2088 + CACGGUCAAGUGUGCAG 17 2573 BCL11A-2089 + ACGGUCAAGUGUGCAGC 17 2574 BCL11A-2090 + GUCAAGUGUGCAGCGGG 17 2575 BCL11A-2091 + CCACAAUAGUGAGAAAG 17 2576 BCL11A-2092 + GUGAGAAAGUGGCACUG 17 2577 BCL11A-2093 + AAAGUGGCACUGUGGAA 17 2578 BCL11A-2094 + AAGUGGCACUGUGGAAA 17 2579 BCL11A-2095 + AGUGGCACUGUGGAAAG 17 2580 BCL11A-2096 + CUGUGGAAAGGGGCCCC 17 2581 BCL11A-2097 + CGGCGCUCCUGAGUCCG 17 2582 BCL11A-2098 + UCCUGAGUCCGCGGAGU 17 2583 BCL11A-2099 + CCUGAGUCCGCGGAGUC 17 2584 BCL11A-2100 + GUCCGCGGAGUCGGGAG 17 2585 BCL11A-2101 + UCCGCGGAGUCGGGAGA 17 2586 BCL11A-2102 + CCGCGGAGUCGGGAGAG 17 2587 BCL11A-2103 + AGUCGGGAGAGGGGCCG 17 2588 BCL11A-2104 + GAGAGGGGCCGCGGCGA 17 2589 BCL11A-2105 + AGAGGGGCCGCGGCGAC 17 2590 BCL11A-2106 + GAGGGGCCGCGGCGACG 17 2591 BCL11A-2107 + GGCGACGGGGAGAGCCG 17 2592 BCL11A-2108 + GCGACGGGGAGAGCCGU 17 2593 BCL11A-2109 + GGGGAGAGCCGUGGGAC 17 2594 BCL11A-2110 + GGGAGAGCCGUGGGACC 17 2595 BCL11A-2111 + GAGCCGUGGGACCGGGA 17 2596 BCL11A-2112 + CGUGGGACCGGGAAGGA 17 2597 BCL11A-2113 + GUGGGACCGGGAAGGAC 17 2598 BCL11A-2114 + GGGAAGGACGGGAGACG 17 2599 BCL11A-2115 + AGGACGGGAGACGCGGC 17 2600 BCL11A-2116 + ACUGCCGCCUUUUGUUC 17 2601 BCL11A-2117 + CCUUUUGUUCCGGCCAG 17 2602 BCL11A-2118 + UUUGUUCCGGCCAGAGG 17 2603 BCL11A-2119 + UUGUUCCGGCCAGAGGU 17 2604 BCL11A-2120 + CCCGCUGCCUUUUGUGC 17 2605 BCL11A-2121 + GCCGCCGCCGCCGCCGA 17 2606 BCL11A-2122 + CCGCCGCCGCCGCCGAA 17 2607 BCL11A-2123 + CGCCGCCGCCGAAGGGC 17 2608 BCL11A-2124 + GCCGAAGGGCAGGAGCU 17 2609 BCL11A-2125 + CCGAAGGGCAGGAGCUA 17 2610 BCL11A-2126 + AGGGCAGGAGCUAGGGC 17 2611 BCL11A-2127 + GGGCAGGAGCUAGGGCC 17 2612 BCL11A-2128 + GGCAGGAGCUAGGGCCG 17 2613 BCL11A-2129 + GCAGGAGCUAGGGCCGG 17 2614 BCL11A-2130 + GGAGCUAGGGCCGGGGG 17 2615 BCL11A-2131 + GCUAGGGCCGGGGGAGG 17 2616 BCL11A-2132 + AGGGCCGGGGGAGGAGG 17 2617 BCL11A-2133 + CCGGGGGAGGAGGCGGC 17 2618 BCL11A-2134 + CGGGGGAGGAGGCGGCC 17 2619 BCL11A-2135 + GGGGGAGGAGGCGGCCG 17 2620 BCL11A-2136 + GGGGAGGAGGCGGCCGG 17 2621 BCL11A-2137 + AGGCGGCCGGGGGCACG 17 2622 BCL11A-2138 + GGCGGCCGGGGGCACGC 17 2623 BCL11A-2139 + CCGGGGGCACGCGGGAG 17 2624 BCL11A-2140 + CGGGGGCACGCGGGAGA 17 2625 BCL11A-2141 + GGGCACGCGGGAGAGGG 17 2626 BCL11A-2142 + GGCACGCGGGAGAGGGA 17 2627 BCL11A-2143 + ACGCGGGAGAGGGAGGG 17 2628 BCL11A-2144 + CGCGGGAGAGGGAGGGA 17 2629 BCL11A-2145 + GAGGGAGGGAGGGAGCC 17 2630 BCL11A-2146 + CCCGGACUGCUGCCUCC 17 2631 BCL11A-2147 + CCGGACUGCUGCCUCCU 17 2632 BCL11A-2148 + UCCCGACCGAACCUCAG 17 2633 BCL11A-2149 + GAACCUCAGAGGCAGCA 17 2634 BCL11A-2150 + GGCAGCAAGGAGAAGAC 17 2635 BCL11A-2151 + AUAAAAUAAAUAAAACA 17 2636

Table 3B provides exemplary targeting domains for repressing (i.e., knocking down or decreasing) expression of the BCL11A gene. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule to cause a steric block in the promoter region to block transcription elongation resulting in the repression of the BCL6A gene. Any of the targeting domains in the table can be used with a S. aureus eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 3B S. aureus gRNA targets for BCL11A knockdown Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO BCL11A-2152 − CAGUCUUCUCCUUGCUGCCU 20 2637 BCL11A-2153 − UUGCUGCCUCUGAGGUUCGG 20 2638 BCL11A-2154 − UGCUGCCUCUGAGGUUCGGU 20 2639 BCL11A-2155 − GCUGCCUCUGAGGUUCGGUC 20 2640 BCL11A-2156 − UGCCUCUGAGGUUCGGUCGG 20 2641 BCL11A-2157 − GCCUCUGAGGUUCGGUCGGG 20 2642 BCL11A-2158 − CCUCUGAGGUUCGGUCGGGA 20 2643 BCL11A-2159 − CUCUGAGGUUCGGUCGGGAG 20 2644 BCL11A-216O − CUGAGGUUCGGUCGGGAGGG 20 2645 BCL11A-2161 − AGGGGAGGGCAGCGGCAACC 20 2646 BCL11A-2162 − GGGGAGGGCAGCGGCAACCC 20 2647 BCL11A-2163 − GCAACCCAGGAGGCAGCAGU 20 2648 BCL11A-2164 − GCGGCGGCGGCGGCGGCGGC 20 2649 BCL11A-2165 − CGGCGGCGGCGGCGGCGGCG 20 2650 BCL11A-2166 − GGCGGCGGCGGCGGCGGCGC 20 2651 BCL11A-2167 − CGGCGGCGGCGGCGGCGCGG 20 2652 BCL11A-2168 − GGCGGCGCGGGAGGGCAAGC 20 2653 BCL11A-2169 − CGGCGCGGGAGGGCAAGCGC 20 2654 BCL11A-2170 − GGCGCGGGAGGGCAAGCGCG 20 2655 BCL11A-2171 − AGGAGCCGGCACAAAAGGCA 20 2656 BCL11A-2172 − GGAGCCGGCACAAAAGGCAG 20 2657 BCL11A-2173 − GGACAAACACCCACCUCUGG 20 2658 BCL11A-2174 − GACAAACACCCACCUCUGGC 20 2659 BCL11A-2175 − GCGGCCCCUCUCCCGACUCC 20 2660 BCL11A-2176 − CUCUCCCGACUCCGCGGACU 20 2661 BCL11A-2177 − UCUCCCGACUCCGCGGACUC 20 2662 BCL11A-2178 − ACUCCGCGGACUCAGGAGCG 20 2663 BCL11A-2179 − CUCCGCGGACUCAGGAGCGC 20 2664 BCL11A-2180 − UCCGCGGACUCAGGAGCGCC 20 2665 BCL11A-2181 − AGUGCCACUUUCUCACUAUU 20 2666 BCL11A-2182 − GUGCCACUUUCUCACUAUUG 20 2667 BCL11A-2183 − UGCCACUUUCUCACUAUUGU 20 2668 BCL11A-2184 − CUCCCGCUGCACACUUGACC 20 2669 BCL11A-2185 − CAGUCUCACCUCUUUUCUCC 20 2670 BCL11A-2186 − AGUCUCACCUCUUUUCUCCC 20 2671 BCL11A-2187 − GUCUCACCUCUUUUCUCCCC 20 2672 BCL11A-2188 − UACCCCCCCAUUUUCUUACG 20 2673 BCL11A-2189 − CCCCCAUUUUCUUACGGUGA 20 2674 BCL11A-2190 − CCCCAUUUUCUUACGGUGAG 20 2675 BCL11A-2191 − CCCAUUUUCUUACGGUGAGU 20 2676 BCL11A-2192 − UCCCACCCCCAGGUUUGCAU 20 2677 BCL11A-2193 − UUCAUUAUUUUGCAAAACUG 20 2678 BCL11A-2194 − UCAUUAUUUUGCAAAACUGG 20 2679 BCL11A-2195 − UAUUUUGCAAAACUGGCGGG 20 2680 BCL11A-2196 − AUUUUGCAAAACUGGCGGGG 20 2681 BCL11A-2197 − UUUUGCAAAACUGGCGGGGC 20 2682 BCL11A-2198 − UUUGCAAAACUGGCGGGGCG 20 2683 BCL11A-2199 − UUGCAAAACUGGCGGGGCGG 20 2684 BCL11A-2200 − UGCAAAACUGGCGGGGCGGG 20 2685 BCL11A-2201 − GCAAAACUGGCGGGGCGGGG 20 2686 BCL11A-2202 − CAAAACUGGCGGGGCGGGGG 20 2687 BCL11A-2203 − ACUGGCGGGGCGGGGGGGGA 20 2688 BCL11A-2204 − CUGGCGGGGCGGGGGGGGAG 20 2689 BCL11A-2205 − UGGAAUCAUUGCAUUCCUUU 20 2690 BCL11A-2206 − UCAUUGCAUUCCUUUUCGAA 20 2691 BCL11A-2207 − AUUGCAUUCCUUUUCGAAAA 20 2692 BCL11A-2208 − UCGAAAAGAGAAAUAAAGCG 20 2693 BCL11A-2209 − CGAAAAGAGAAAUAAAGCGG 20 2694 BCL11A-2210 − AAGAGAAAUAAAGCGGCGGA 20 2695 BCL11A-2211 − AGAGAAAUAAAGCGGCGGAA 20 2696 BCL11A-2212 − AGAAAUAAAGCGGCGGAAAG 20 2697 BCL11A-2213 − GAAAUAAAGCGGCGGAAAGG 20 2698 BCL11A-2214 − UAAAGCGGCGGAAAGGAGGA 20 2699 BCL11A-2215 − AAGCGGCGGAAAGGAGGAAA 20 2700 BCL11A-2216 − AGCGGCGGAAAGGAGGAAAG 20 2701 BCL11A-2217 − CGGCGGAAAGGAGGAAAGAG 20 2702 BCL11A-2218 − GGCGGAAAGGAGGAAAGAGG 20 2703 BCL11A-2219 − AUACACGGCAAUGGUUCCAG 20 2704 BCL11A-2220 − UACACGGCAAUGGUUCCAGA 20 2705 BCL11A-2221 − CGGCAAUGGUUCCAGAUGGG 20 2706 BCL11A-2222 − GCAAUGGUUCCAGAUGGGAU 20 2707 BCL11A-2223 − UAUCUCUUUUACCUCGACUC 20 2708 BCL11A-2224 − AUCUCUUUUACCUCGACUCU 20 2709 BCL11A-2225 − GACUCUCGGAGGUUUUUCUC 20 2710 BCL11A-2226 − AAUAAUUAUUAUUACUAUUA 20 2711 BCL11A-2227 − ACUAUUAUUGGGUUACUUAC 20 2712 BCL11A-2228 − UAUUAUUGGGUUACUUACGC 20 2713 BCL11A-2229 − UCUUCUCCUUGCUGCCU 17 2714 BCL11A-2230 − CUGCCUCUGAGGUUCGG 17 2715 BCL11A-2231 − UGCCUCUGAGGUUCGGU 17 2716 BCL11A-2232 − GCCUCUGAGGUUCGGUC 17 2717 BCL11A-2233 − CUCUGAGGUUCGGUCGG 17 2718 BCL11A-2234 − UCUGAGGUUCGGUCGGG 17 2719 BCL11A-2235 − CUGAGGUUCGGUCGGGA 17 2720 BCL11A-2236 − UGAGGUUCGGUCGGGAG 17 2721 BCL11A-2237 − AGGUUCGGUCGGGAGGG 17 2722 BCL11A-2238 − GGAGGGCAGCGGCAACC 17 2723 BCL11A-2239 − GAGGGCAGCGGCAACCC 17 2724 BCL11A-2240 − ACCCAGGAGGCAGCAGU 17 2725 BCL11A-2241 − GCGGCGGCGGCGGCGGC 17 2726 BCL11A-2242 − CGGCGGCGGCGGCGGCG 17 2727 BCL11A-2243 − GGCGGCGGCGGCGGCGC 17 2728 BCL11A-2244 − CGGCGGCGGCGGCGCGG 17 2729 BCL11A-2245 − GGCGCGGGAGGGCAAGC 17 2730 BCL11A-2246 − CGCGGGAGGGCAAGCGC 17 2731 BCL11A-2247 − GCGGGAGGGCAAGCGCG 17 2732 BCL11A-2248 − AGCCGGCACAAAAGGCA 17 2733 BCL11A-2249 − GCCGGCACAAAAGGCAG 17 2734 BCL11A-2250 − CAAACACCCACCUCUGG 17 2735 BCL11A-2251 − AAACACCCACCUCUGGC 17 2736 BCL11A-2252 − GCCCCUCUCCCGACUCC 17 2737 BCL11A-2253 − UCCCGACUCCGCGGACU 17 2738 BCL11A-2254 − CCCGACUCCGCGGACUC 17 2739 BCL11A-2255 − CCGCGGACUCAGGAGCG 17 2740 BCL11A-2256 − CGCGGACUCAGGAGCGC 17 2741 BCL11A-2257 − GCGGACUCAGGAGCGCC 17 2742 BCL11A-2258 − GCCACUUUCUCACUAUU 17 2743 BCL11A-2259 − CCACUUUCUCACUAUUG 17 2744 BCL11A-2260 − CACUUUCUCACUAUUGU 17 2745 BCL11A-2261 − CCGCUGCACACUUGACC 17 2746 BCL11A-2262 − UCUCACCUCUUUUCUCC 17 2747 BCL11A-2263 − CUCACCUCUUUUCUCCC 17 2748 BCL11A-2264 − UCACCUCUUUUCUCCCC 17 2749 BCL11A-2265 − CCCCCCAUUUUCUUACG 17 2750 BCL11A-2266 − CCAUUUUCUUACGGUGA 17 2751 BCL11A-2267 − CAUUUUCUUACGGUGAG 17 2752 BCL11A-2268 − AUUUUCUUACGGUGAGU 17 2753 BCL11A-2269 − CACCCCCAGGUUUGCAU 17 2754 BCL11A-2270 − AUUAUUUUGCAAAACUG 17 2755 BCL11A-2271 − UUAUUUUGCAAAACUGG 17 2756 BCL11A-2272 − UUUGCAAAACUGGCGGG 17 2757 BCL11A-2273 − UUGCAAAACUGGCGGGG 17 2758 BCL11A-2274 − UGCAAAACUGGCGGGGC 17 2759 BCL11A-2275 − GCAAAACUGGCGGGGCG 17 2760 BCL11A-2276 − CAAAACUGGCGGGGCGG 17 2761 BCL11A-2277 − AAAACUGGCGGGGCGGG 17 2762 BCL11A-2278 − AAACUGGCGGGGCGGGG 17 2763 BCL11A-2279 − AACUGGCGGGGCGGGGG 17 2764 BCL11A-2280 − GGCGGGGCGGGGGGGGA 17 2765 BCL11A-2281 − GCGGGGCGGGGGGGGAG 17 2766 BCL11A-2282 − AAUCAUUGCAUUCCUUU 17 2767 BCL11A-2283 − UUGCAUUCCUUUUCGAA 17 2768 BCL11A-2284 − GCAUUCCUUUUCGAAAA 17 2769 BCL11A-2285 − AAAAGAGAAAUAAAGCG 17 2770 BCL11A-2286 − AAAGAGAAAUAAAGCGG 17 2771 BCL11A-2287 − AGAAAUAAAGCGGCGGA 17 2772 BCL11A-2288 − GAAAUAAAGCGGCGGAA 17 2773 BCL11A-2289 − AAUAAAGCGGCGGAAAG 17 2774 BCL11A-2290 − AUAAAGCGGCGGAAAGG 17 2775 BCL11A-2291 − AGCGGCGGAAAGGAGGA 17 2776 BCL11A-2292 − CGGCGGAAAGGAGGAAA 17 2777 BCL11A-2293 − GGCGGAAAGGAGGAAAG 17 2778 BCL11A-2294 − CGGAAAGGAGGAAAGAG 17 2779 BCL11A-2295 − GGAAAGGAGGAAAGAGG 17 2780 BCL11A-2296 − CACGGCAAUGGUUCCAG 17 2781 BCL11A-2297 − ACGGCAAUGGUUCCAGA 17 2782 BCL11A-2298 − CAAUGGUUCCAGAUGGG 17 2783 BCL11A-2299 − AUGGUUCCAGAUGGGAU 17 2784 BCL11A-2300 − CUCUUUUACCUCGACUC 17 2785 BCL11A-2301 − UCUUUUACCUCGACUCU 17 2786 BCL11A-2302 − UCUCGGAGGUUUUUCUC 17 2787 BCL11A-2303 − AAUUAUUAUUACUAUUA 17 2788 BCL11A-2304 − AUUAUUGGGUUACUUAC 17 2789 BCL11A-2305 − UAUUGGGUUACUUACGC 17 2790 BCL11A-2306 + CGAACCUCAGAGGCAGCAAG 20 2791 BCL11A-2307 + ACCGAACCUCAGAGGCAGCA 20 2792 BCL11A-2308 + GACCGAACCUCAGAGGCAGC 20 2793 BCL11A-2309 + CUCCCCUCCCGACCGAACCU 20 2794 BCL11A-2310 + CCGCUGCCCUCCCCUCCCGA 20 2795 BCL11A-2311 + GGAGCCCGGACUGCUGCCUC 20 2796 BCL11A-2312 + GGGAGAGGGAGGGAGGGAGC 20 2797 BCL11A-2313 + GCACGCGGGAGAGGGAGGGA 20 2798 BCL11A-2314 + GGCACGCGGGAGAGGGAGGG 20 2799 BCL11A-2315 + GGGCACGCGGGAGAGGGAGG 20 2800 BCL11A-2316 + GGGGGCACGCGGGAGAGGGA 20 2801 BCL11A-2317 + CGGGGGCACGCGGGAGAGGG 20 2802 BCL11A-2318 + CCGGGGGCACGCGGGAGAGG 20 2803 BCL11A-2319 + GGCCGGGGGCACGCGGGAGA 20 2804 BCL11A-2320 + CGGCCGGGGGCACGCGGGAG 20 2805 BCL11A-2321 + GCGGCCGGGGGCACGCGGGA 20 2806 BCL11A-2322 + AGGCGGCCGGGGGCACGCGG 20 2807 BCL11A-2323 + GGAGGCGGCCGGGGGCACGC 20 2808 BCL11A-2324 + AGGAGGCGGCCGGGGGCACG 20 2809 BCL11A-2325 + GAGGAGGCGGCCGGGGGCAC 20 2810 BCL11A-2326 + GGCCGGGGGAGGAGGCGGCC 20 2811 BCL11A-2327 + GGGCCGGGGGAGGAGGCGGC 20 2812 BCL11A-2328 + AGGGCCGGGGGAGGAGGCGG 20 2813 BCL11A-2329 + GCAGGAGCUAGGGCCGGGGG 20 2814 BCL11A-2330 + GGCAGGAGCUAGGGCCGGGG 20 2815 BCL11A-2331 + AGGGCAGGAGCUAGGGCCGG 20 2816 BCL11A-2332 + AAGGGCAGGAGCUAGGGCCG 20 2817 BCL11A-2333 + GAAGGGCAGGAGCUAGGGCC 20 2818 BCL11A-2334 + CGAAGGGCAGGAGCUAGGGC 20 2819 BCL11A-2335 + CCGAAGGGCAGGAGCUAGGG 20 2820 BCL11A-2336 + CGCCGCCGAAGGGCAGGAGC 20 2821 BCL11A-2337 + CGCCGCCGCCGCCGAAGGGC 20 2822 BCL11A-2338 + CCGCCGCCGCCGCCGAAGGG 20 2823 BCL11A-2339 + CGCCGCCGCCGCCGCCGCCG 20 2824 BCL11A-2340 + CGCCGCCGCCGCCGCCGCCG 20 2825 BCL11A-2341 + GCCUUUUGUUCCGGCCAGAG 20 2826 BCL11A-2342 + CUGCCGCCUUUUGUUCCGGC 20 2827 BCL11A-2343 + GCCGUGGGACCGGGAAGGAC 20 2828 BCL11A-2344 + AGCCGUGGGACCGGGAAGGA 20 2829 BCL11A-2345 + GAGCCGUGGGACCGGGAAGG 20 2830 BCL11A-2346 + GGGAGAGCCGUGGGACCGGG 20 2831 BCL11A-2347 + ACGGGGAGAGCCGUGGGACC 20 2832 BCL11A-2348 + GACGGGGAGAGCCGUGGGAC 20 2833 BCL11A-2349 + CGACGGGGAGAGCCGUGGGA 20 2834 BCL11A-2350 + CGCGGCGACGGGGAGAGCCG 20 2835 BCL11A-2351 + CCGCGGCGACGGGGAGAGCC 20 2836 BCL11A-2352 + AGAGGGGCCGCGGCGACGGG 20 2837 BCL11A-2353 + GGAGAGGGGCCGCGGCGACG 20 2838 BCL11A-2354 + GGGAGAGGGGCCGCGGCGAC 20 2839 BCL11A-2355 + CGGGAGAGGGGCCGCGGCGA 20 2840 BCL11A-2356 + UCGGGAGAGGGGCCGCGGCG 20 2841 BCL11A-2357 + UGAGUCCGCGGAGUCGGGAG 20 2842 BCL11A-2358 + CUGAGUCCGCGGAGUCGGGA 20 2843 BCL11A-2359 + UCCUGAGUCCGCGGAGUCGG 20 2844 BCL11A-2360 + GCUCCUGAGUCCGCGGAGUC 20 2845 BCL11A-2361 + CGCUCCUGAGUCCGCGGAGU 20 2846 BCL11A-2362 + GCGCUCCUGAGUCCGCGGAG 20 2847 BCL11A-2363 + CCCCGGCGCUCCUGAGUCCG 20 2848 BCL11A-2364 + CCCCCGGCGCUCCUGAGUCC 20 2849 BCL11A-2365 + GAAAGGGGCCCCCGGCGCUC 20 2850 BCL11A-2366 + GAGAAAGUGGCACUGUGGAA 20 2851 BCL11A-2367 + UGAGAAAGUGGCACUGUGGA 20 2852 BCL11A-2368 + AUAGUGAGAAAGUGGCACUG 20 2853 BCL11A-2369 + AAUAGUGAGAAAGUGGCACU 20 2854 BCL11A-2370 + GUAGUCAUCCCCACAAUAGU 20 2855 BCL11A-2371 + AAGUAGUCAUCCCCACAAUA 20 2856 BCL11A-2372 + ACGGUCAAGUGUGCAGCGGG 20 2857 BCL11A-2373 + CACGGUCAAGUGUGCAGCGG 20 2858 BCL11A-2374 + CUCACGGUCAAGUGUGCAGC 20 2859 BCL11A-2375 + GCUCACGGUCAAGUGUGCAG 20 2860 BCL11A-2376 + CGCUCACGGUCAAGUGUGCA 20 2861 BCL11A-2377 + AAAAGAGGUGAGACUGGCUU 20 2862 BCL11A-2378 + GAUUCCCGGGGAGAAAAGAG 20 2863 BCL11A-2379 + AAAACGAUUCCCGGGGAGAA 20 2864 BCL11A-2380 + UCUAAAAAACGAUUCCCGGG 20 2865 BCL11A-2381 + AGUCUAAAAAACGAUUCCCG 20 2866 BCL11A-2382 + AAGUCUAAAAAACGAUUCCC 20 2867 BCL11A-2383 + CAAGUCUAAAAAACGAUUCC 20 2868 BCL11A-2384 + ACAAGUCUAAAAAACGAUUC 20 2869 BCL11A-2385 + AAUGGGGGGGUAGGGAGGGA 20 2870 BCL11A-2386 + AGAAAAUGGGGGGGUAGGGA 20 2871 BCL11A-2387 + AAGAAAAUGGGGGGGUAGGG 20 2872 BCL11A-2388 + UAAGAAAAUGGGGGGGUAGG 20 2873 BCL11A-2389 + CGUAAGAAAAUGGGGGGGUA 20 2874 BCL11A-2390 + CCGUAAGAAAAUGGGGGGGU 20 2875 BCL11A-2391 + ACCGUAAGAAAAUGGGGGGG 20 2876 BCL11A-2392 + CACUCACCGUAAGAAAAUGG 20 2877 BCL11A-2393 + CCACUCACCGUAAGAAAAUG 20 2878 BCL11A-2394 + CCCACUCACCGUAAGAAAAU 20 2879 BCL11A-2395 + UCCCACUCACCGUAAGAAAA 20 2880 BCL11A-2396 + UUCCCACUCACCGUAAGAAA 20 2881 BCL11A-2397 + GGUUGCUUCCCACUCACCGU 20 2882 BCL11A-2398 + GGUGGGAGCUGGUGGGGAAA 20 2883 BCL11A-2399 + GGGUGGGAGCUGGUGGGGAA 20 2884 BCL11A-2400 + GGGGUGGGAGCUGGUGGGGA 20 2885 BCL11A-2401 + CCUGGGGGUGGGAGCUGGUG 20 2886 BCL11A-2402 + ACCUGGGGGUGGGAGCUGGU 20 2887 BCL11A-2403 + AACCUGGGGGUGGGAGCUGG 20 2888 BCL11A-2404 + AAACCUGGGGGUGGGAGCUG 20 2889 BCL11A-2405 + UCACAUGCAAACCUGGGGGU 20 2890 BCL11A-2406 + CUCACAUGCAAACCUGGGGG 20 2891 BCL11A-2407 + ACUCACAUGCAAACCUGGGG 20 2892 BCL11A-2408 + AACAACUCACAUGCAAACCU 20 2893 BCL11A-2409 + GAACAACUCACAUGCAAACC 20 2894 BCL11A-2410 + CGAACAACUCACAUGCAAAC 20 2895 BCL11A-2411 + UAAUGAACAAUGCUAAGGUU 20 2896 BCL11A-2412 + CCCGCCAGUUUUGCAAAAUA 20 2897 BCL11A-2413 + CUUUAUUUCUCUUUUCGAAA 20 2898 BCL11A-2414 + GCUUUAUUUCUCUUUUCGAA 20 2899 BCL11A-2415 + CCGCCGCUUUAUUUCUCUUU 20 2900 BCL11A-2416 + CCAUUGCCGUGUAUGCACUU 20 2901 BCL11A-2417 + GAAAAAACCCUCAUCCCAUC 20 2902 BCL11A-2418 + GGAAAAAACCCUCAUCCCAU 20 2903 BCL11A-2419 + CGAGGUAAAAGAGAUAAAGG 20 2904 BCL11A-2420 + UCGAGGUAAAAGAGAUAAAG 20 2905 BCL11A-2421 + GUCGAGGUAAAAGAGAUAAA 20 2906 BCL11A-2422 + AGUCGAGGUAAAAGAGAUAA 20 2907 BCL11A-2423 + GAGUCGAGGUAAAAGAGAUA 20 2908 BCL11A-2424 + ACCUCCGAGAGUCGAGGUAA 20 2909 BCL11A-2425 + ACGAGAAAAACCUCCGAGAG 20 2910 BCL11A-2426 + UUUUCACGAGAAAAACCUCC 20 2911 BCL11A-2427 + AUUUUUCACGAGAAAAACCU 20 2912 BCL11A-2428 + UGCAUUUUUAAAUUUUUCAC 20 2913 BCL11A-2429 + CAUGCAUUUUUAAAUUUUUC 20 2914 BCL11A-2430 + AGCAAAAGCGAGGGGGAGAG 20 2915 BCL11A-2431 + AAGCAAAAGCGAGGGGGAGA 20 2916 BCL11A-2432 + AGAAGCAAAAGCGAGGGGGA 20 2917 BCL11A-2433 + CUAGAAGCAAAAGCGAGGGG 20 2918 BCL11A-2434 + GACUAGAAGCAAAAGCGAGG 20 2919 BCL11A-2435 + GGACUAGAAGCAAAAGCGAG 20 2920 BCL11A-2436 + AGGACUAGAAGCAAAAGCGA 20 2921 BCL11A-2437 + CAGGACUAGAAGCAAAAGCG 20 2922 BCL11A-2438 + GCAGGACUAGAAGCAAAAGC 20 2923 BCL11A-2439 + GCGCAGGACUAGAAGCAAAA 20 2924 BCL11A-2440 + AUCACGAGAGCGCGCAGGAC 20 2925 BCL11A-2441 + UUAAUAAUCACGAGAGCGCG 20 2926 BCL11A-2442 + UAAUAAUUAUUAAUAAUCAC 20 2927 BCL11A-2443 + AAUAAUAAUUAUUAAUAAUC 20 2928 BCL11A-2444 + ACCUCAGAGGCAGCAAG 17 2929 BCL11A-2445 + GAACCUCAGAGGCAGCA 17 2930 BCL11A-2446 + CGAACCUCAGAGGCAGC 17 2931 BCL11A-2447 + CCCUCCCGACCGAACCU 17 2932 BCL11A-2448 + CUGCCCUCCCCUCCCGA 17 2933 BCL11A-2449 + GCCCGGACUGCUGCCUC 17 2934 BCL11A-2450 + AGAGGGAGGGAGGGAGC 17 2935 BCL11A-2451 + CGCGGGAGAGGGAGGGA 17 2936 BCL11A-2452 + ACGCGGGAGAGGGAGGG 17 2937 BCL11A-2453 + CACGCGGGAGAGGGAGG 17 2938 BCL11A-2454 + GGCACGCGGGAGAGGGA 17 2939 BCL11A-2455 + GGGCACGCGGGAGAGGG 17 2940 BCL11A-2456 + GGGGCACGCGGGAGAGG 17 2941 BCL11A-2457 + CGGGGGCACGCGGGAGA 17 2942 BCL11A-2458 + CCGGGGGCACGCGGGAG 17 2943 BCL11A-2459 + GCCGGGGGCACGCGGGA 17 2944 BCL11A-2460 + CGGCCGGGGGCACGCGG 17 2945 BCL11A-2461 + GGCGGCCGGGGGCACGC 17 2946 BCL11A-2462 + AGGCGGCCGGGGGCACG 17 2947 BCL11A-2463 + GAGGCGGCCGGGGGCAC 17 2948 BCL11A-2464 + CGGGGGAGGAGGCGGCC 17 2949 BCL11A-2465 + CCGGGGGAGGAGGCGGC 17 2950 BCL11A-2466 + GCCGGGGGAGGAGGCGG 17 2951 BCL11A-2467 + GGAGCUAGGGCCGGGGG 17 2952 BCL11A-2468 + AGGAGCUAGGGCCGGGG 17 2953 BCL11A-2469 + GCAGGAGCUAGGGCCGG 17 2954 BCL11A-2470 + GGCAGGAGCUAGGGCCG 17 2955 BCL11A-2471 + GGGCAGGAGCUAGGGCC 17 2956 BCL11A-2472 + AGGGCAGGAGCUAGGGC 17 2957 BCL11A-2473 + AAGGGCAGGAGCUAGGG 17 2958 BCL11A-2474 + CGCCGAAGGGCAGGAGC 17 2959 BCL11A-2475 + CGCCGCCGCCGAAGGGC 17 2960 BCL11A-2476 + CCGCCGCCGCCGAAGGG 17 2961 BCL11A-2477 + CGCCGCCGCCGCCGCCG 17 2962 BCL11A-2478 + CGCCGCCGCCGCCGCCG 17 2963 BCL11A-2479 + UUUUGUUCCGGCCAGAG 17 2964 BCL11A-2480 + CCGCCUUUUGUUCCGGC 17 2965 BCL11A-2481 + GUGGGACCGGGAAGGAC 17 2966 BCL11A-2482 + CGUGGGACCGGGAAGGA 17 2967 BCL11A-2483 + CCGUGGGACCGGGAAGG 17 2968 BCL11A-2484 + AGAGCCGUGGGACCGGG 17 2969 BCL11A-2485 + GGGAGAGCCGUGGGACC 17 2970 BCL11A-2486 + GGGGAGAGCCGUGGGAC 17 2971 BCL11A-2487 + CGGGGAGAGCCGUGGGA 17 2972 BCL11A-2488 + GGCGACGGGGAGAGCCG 17 2973 BCL11A-2489 + CGGCGACGGGGAGAGCC 17 2974 BCL11A-2490 + GGGGCCGCGGCGACGGG 17 2975 BCL11A-2491 + GAGGGGCCGCGGCGACG 17 2976 BCL11A-2492 + AGAGGGGCCGCGGCGAC 17 2977 BCL11A-2493 + GAGAGGGGCCGCGGCGA 17 2978 BCL11A-2494 + GGAGAGGGGCCGCGGCG 17 2979 BCL11A-2495 + GUCCGCGGAGUCGGGAG 17 2980 BCL11A-2496 + AGUCCGCGGAGUCGGGA 17 2981 BCL11A-2497 + UGAGUCCGCGGAGUCGG 17 2982 BCL11A-2498 + CCUGAGUCCGCGGAGUC 17 2983 BCL11A-2499 + UCCUGAGUCCGCGGAGU 17 2984 BCL11A-2500 + CUCCUGAGUCCGCGGAG 17 2985 BCL11A-2501 + CGGCGCUCCUGAGUCCG 17 2986 BCL11A-2502 + CCGGCGCUCCUGAGUCC 17 2987 BCL11A-2503 + AGGGGCCCCCGGCGCUC 17 2988 BCL11A-2504 + AAAGUGGCACUGUGGAA 17 2989 BCL11A-2505 + GAAAGUGGCACUGUGGA 17 2990 BCL11A-2506 + GUGAGAAAGUGGCACUG 17 2991 BCL11A-2507 + AGUGAGAAAGUGGCACU 17 2992 BCL11A-2508 + GUCAUCCCCACAAUAGU 17 2993 BCL11A-2509 + UAGUCAUCCCCACAAUA 17 2994 BCL11A-2510 + GUCAAGUGUGCAGCGGG 17 2995 BCL11A-2511 + GGUCAAGUGUGCAGCGG 17 2996 BCL11A-2512 + ACGGUCAAGUGUGCAGC 17 2997 BCL11A-2513 + CACGGUCAAGUGUGCAG 17 2998 BCL11A-2514 + UCACGGUCAAGUGUGCA 17 2999 BCL11A-2515 + AGAGGUGAGACUGGCUU 17 3000 BCL11A-2516 + UCCCGGGGAGAAAAGAG 17 3001 BCL11A-2517 + ACGAUUCCCGGGGAGAA 17 3002 BCL11A-2518 + AAAAAACGAUUCCCGGG 17 3003 BCL11A-2519 + CUAAAAAACGAUUCCCG 17 3004 BCL11A-2520 + UCUAAAAAACGAUUCCC 17 3005 BCL11A-2521 + GUCUAAAAAACGAUUCC 17 3006 BCL11A-2522 + AGUCUAAAAAACGAUUC 17 3007 BCL11A-2523 + GGGGGGGUAGGGAGGGA 17 3008 BCL11A-2524 + AAAUGGGGGGGUAGGGA 17 3009 BCL11A-2525 + AAAAUGGGGGGGUAGGG 17 3010 BCL11A-2526 + GAAAAUGGGGGGGUAGG 17 3011 BCL11A-2527 + AAGAAAAUGGGGGGGUA 17 3012 BCL11A-2528 + UAAGAAAAUGGGGGGGU 17 3013 BCL11A-2529 + GUAAGAAAAUGGGGGGG 17 3014 BCL11A-2530 + UCACCGUAAGAAAAUGG 17 3015 BCL11A-2531 + CUCACCGUAAGAAAAUG 17 3016 BCL11A-2532 + ACUCACCGUAAGAAAAU 17 3017 BCL11A-2533 + CACUCACCGUAAGAAAA 17 3018 BCL11A-2534 + CCACUCACCGUAAGAAA 17 3019 BCL11A-2535 + UGCUUCCCACUCACCGU 17 3020 BCL11A-2536 + GGGAGCUGGUGGGGAAA 17 3021 BCL11A-2537 + UGGGAGCUGGUGGGGAA 17 3022 BCL11A-2538 + GUGGGAGCUGGUGGGGA 17 3023 BCL11A-2539 + GGGGGUGGGAGCUGGUG 17 3024 BCL11A-2540 + UGGGGGUGGGAGCUGGU 17 3025 BCL11A-2541 + CUGGGGGUGGGAGCUGG 17 3026 BCL11A-2542 + CCUGGGGGUGGGAGCUG 17 3027 BCL11A-2543 + CAUGCAAACCUGGGGGU 17 3028 BCL11A-2544 + ACAUGCAAACCUGGGGG 17 3029 BCL11A-2545 + CACAUGCAAACCUGGGG 17 3030 BCL11A-2546 + AACUCACAUGCAAACCU 17 3031 BCL11A-2547 + CAACUCACAUGCAAACC 17 3032 BCL11A-2548 + ACAACUCACAUGCAAAC 17 3033 BCL11A-2549 + UGAACAAUGCUAAGGUU 17 3034 BCL11A-2550 + GCCAGUUUUGCAAAAUA 17 3035 BCL11A-2551 + UAUUUCUCUUUUCGAAA 17 3036 BCL11A-2552 + UUAUUUCUCUUUUCGAA 17 3037 BCL11A-2553 + CCGCUUUAUUUCUCUUU 17 3038 BCL11A-2554 + UUGCCGUGUAUGCACUU 17 3039 BCL11A-2555 + AAAACCCUCAUCCCAUC 17 3040 BCL11A-2556 + AAAAACCCUCAUCCCAU 17 3041 BCL11A-2557 + GGUAAAAGAGAUAAAGG 17 3042 BCL11A-2558 + AGGUAAAAGAGAUAAAG 17 3043 BCL11A-2559 + GAGGUAAAAGAGAUAAA 17 3044 BCL11A-2560 + CGAGGUAAAAGAGAUAA 17 3045 BCL11A-2561 + UCGAGGUAAAAGAGAUA 17 3046 BCL11A-2562 + UCCGAGAGUCGAGGUAA 17 3047 BCL11A-2563 + AGAAAAACCUCCGAGAG 17 3048 BCL11A-2564 + UCACGAGAAAAACCUCC 17 3049 BCL11A-2565 + UUUCACGAGAAAAACCU 17 3050 BCL11A-2566 + AUUUUUAAAUUUUUCAC 17 3051 BCL11A-2567 + GCAUUUUUAAAUUUUUC 17 3052 BCL11A-2568 + AAAAGCGAGGGGGAGAG 17 3053 BCL11A-2569 + CAAAAGCGAGGGGGAGA 17 3054 BCL11A-2570 + AGCAAAAGCGAGGGGGA 17 3055 BCL11A-2571 + GAAGCAAAAGCGAGGGG 17 3056 BCL11A-2572 + UAGAAGCAAAAGCGAGG 17 3057 BCL11A-2573 + CUAGAAGCAAAAGCGAG 17 3058 BCL11A-2574 + ACUAGAAGCAAAAGCGA 17 3059 BCL11A-2575 + GACUAGAAGCAAAAGCG 17 3060 BCL11A-2576 + GGACUAGAAGCAAAAGC 17 3061 BCL11A-2577 + CAGGACUAGAAGCAAAA 17 3062 BCL11A-2578 + ACGAGAGCGCGCAGGAC 17 3063 BCL11A-2579 + AUAAUCACGAGAGCGCG 17 3064 BCL11A-2580 + UAAUUAUUAAUAAUCAC 17 3065 BCL11A-2581 + AAUAAUUAUUAAUAAUC 17 3066

Table 3C provides exemplary targeting domains for repressing (i.e., knocking down or decreasing) expression of the BCL11A gene. Any of the targeting domains in the table can be used with an N. meningitidis eiCas9 molecule to cause a steric block in the promoter region to block transcription elongation resulting in the repression of the BCL11A gene. Any of the targeting domains in the table can be used with an N. meningitidis eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 3C N. meningitidis gRNA targets for BCL11A knockdown Target SEQ DNA Targeting Site ID gRNA Name Strand Domain Length NO BCL11A-2582 − GCUUCUAGUC 20 3067 CUGCGCGCUC BCL11A-2583 − UCUAGUCCUG 17 3068 CGCGCUC BCL11A-2584 + UUUAGACUUG 20 3069 UACUCACUCC BCL11A-2585 + CAUUCCUUUU 20 3070 CGAAAAGAGA BCL11A-2586 + UUUAGACUUG 17 3071 UACUCAC BCL11A-2587 + CAUUCCUUUU 17 3072 CGAAAAG

Table 4A provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to first tier parameters. The targeting domains bind within first 500 bp of coding sequence downstream of start codon, good orthogonality, start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. Exemplary gRNA pairs are: BCL11A-2607 and BCL11A-2593, BCL11A-2607 and BCL11A-2598, BCL11A-264 and BCL11A-2593, BCL11A-2614 and BCL11A-2598, BCL11A-2589 and BCL11A-2664, BCL11A-2589 and BCL11A-2666, BCL11A-2596 and BCL11A-2664, BCL11A-2596 and BCL11A-2666, BCL11A-2603 and BCL11A-2664, of BCL11A-2603 and BCL11A-2666.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene. For example, gRNA pairs that target upstream (i.e., 5′) of the enhancer region in the BCL11A gene (e.g., 2607 and BCL11A-2593, BCL11A-2607 and BCL11A-2598, BCL11A-264 and BCL11A-2593, or BCL11A-2614 and BCL11A-2598) can be paired with gRNA pairs that target downstream (i.e., 3′) of the enhancer region in the BCL11A gene (e.g., BCL11A-2589 and BCL11A-2664, BCL11A-2589 and BCL11A-2666, BCL11A-2596 and BCL11A-2664, BCL11A-2596 and BCL11A-2666, BCL11A-2603 and BCL11A-2664, of BCL11A-2603 and BCL11A-2666).

TABLE 4A Target SEQ 1st Tier DNA Targeting Site ID gRNA Name Strand Domain Length NO BCL11A-2588 + GAGCUCCAUG 20 3073 UGCAGAACGA BCL11A-2589 + GAGCUCCCAA 17 3074 CGGGCCG BCL11A-2590 − GAGUGCAGAA 20 3075 UAUGCCCCGC BCL11A-2591 + GAUAAACAAU 20 3076 CGUCAUCCUC BCL11A-2592 + GAUGCCAACC 20 3077 UCCACGGGAU BCL11A-2593 − GCAGAAUAUG 17 3078 CCCCGCA BCL11A-2594 − GCAUCCAAUC 20 3079 CCGUGGAGGU BCL11A-2595 + GCCAACCUCC 17 3080 ACGGGAU BCL11A-2596 + GCUCCCAACG 20 3081 GGCCGUGGUC BCL11A-2597 − GGAGCUCUAA 20 3082 UCCCCACGCC

Table 4B provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to second tier parameters. The targeting domains bind within first 500 bp of coding sequence downstream of start codon, good orthogonality, and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 4B Target SEQ 2nd Tier DNA Targeting Site ID gRNA Name Strand Domain Length NO BCL11A-2598 − AGCAUCCAAU 17 3083 CCCGUGG BCL11A-2599 − AGUGCAGAAU 20 3084 AUGCCCCGCA BCL11A-2600 − AUGUCUCGCC 17 3085 GCAAGCA BCL11A-2601 + AUUCCCGUUU 20 3086 GCUUAAGUGC BCL11A-2602 + CAUCCUCUGG 17 3087 CGUGACC BCL11A-2603 + CCCAACGGGC 17 3088 CGUGGUC BCL11A-2604 + CCCCCAAUGG 20 3089 GAAGUUCAUC BCL11A-2605 + CCCGUUUGCU 17 3090 UAAGUGC BCL11A-2606 + CGUCAUCCUC 20 3091 UGGCGUGACC BCL11A-2607 + UCAUCUCGAU 17 3092 UGGUGAA BCL11A-2608 − UCCAAUCCCG 17 3093 UGGAGGU BCL11A-2609 + UCCCGUUUGC 20 3094 UUAAGUGCUG BCL11A-2610 − UGAACCAGAC 20 3095 CACGGCCCGU BCL11A-2611 − UGCAGAAUAU 17 3096 GCCCCGC BCL11A-2612 − UGGCAUCCAG 20 3097 GUCACGCCAG BCL11A-2613 − UUAUCAACGU 17 3098 CAUCUAG BCL11A-2614 + UUCAUCUCGA 17 3099 UUGGUGA

Table 4C provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to third tier parameters. The targeting domains bind within first 500 bp of coding sequence downstream of start codon and start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 4C 3rd Tier Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO BCL11A-2615 − GAAAAAAGCAUCCAAUCCCG 20 3100 BCL11A-2616 − GAACCAGACCACGGCCCGUU 20 3101 BCL11A-2617 + GACCUGGAUGCCAACCUCCA 20 3102 BCL11A-2618 − GAGCUCUAAUCCCCACGCCU 20 3103 BCL11A-2619 − GAUCAUGACCUCCUCACCUG 20 3104 BCL11A-2620 − GAUGAACUUCCCAUUGG 17 3105 BCL11A-2621 − GAUGAUGAACCAGACCA 17 3106 BCL11A-2622 + GAUGCUUUUUUCAUCUCGAU 20 3107 BCL11A-2623 + GCACUCAUCCCAGGCGU 17 3108 BCL11A-2624 + GCAUAUUCUGCACUCAUCCC 20 3109 BCL11A-2625 − GCCAGAUGAACUUCCCAUUG 20 3110 BCL11A-2626 − GCCCGUUGGGAGCUCCAGAA 20 3111 BCL11A-2627 + GCUAUGUGUUCCUGUUU 17 3112 BCL11A-2628 + GCUCCAUGUGCAGAACG 17 3113 BCL11A-2629 − GCUCUAAUCCCCACGCC 17 3114 BCL11A-2630 + GCUGGGGUUUGCCUUGCUUG 20 3115 BCL11A-2631 + GCUUUUUUCAUCUCGAU 17 3116 BCL11A-2632 + GGCACUGCCCACAGGUG 17 3117 BCL11A-2633 + GGCACUGCCCACAGGUGAGG 20 3118 BCL11A-2634 − GGCCCGUUGGGAGCUCCAGA 20 3119 BCL11A-2635 + GGGGUUUGCCUUGCUUG 17 3120 BCL11A-2636 + GUAAGAAUGGCUUCAAG 17 3121 BCL11A-2637 + GUGCAGAACGAGGGGAGGAG 20 3122 BCL11A-2638 − GUGCCAGAUGAACUUCCCAU 20 3123 BCL11A-2639 + GUUCAUCUGGCACUGCCCAC 20 3124 BCL11A-2640 − GUUGGGAGCUCCAGAAG 17 3125

Table 4D provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to forth tier parameters. The targeting domains bind within first 500 bp of coding sequence downstream of start codon and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL0A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 4D 4th Tier Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO BCL11A-2641 − AAAAGCAUCCAAUCCCG 17 3126 BCL11A-2642 − AAAAGCAUCCAAUCCCGUGG 20 3127 BCL11A-2643 + AAAAUAAGAAUGUCCCCCAA 20 3128 BCL11A-2644 + AAACAAUCGUCAUCCUC 17 3129 BCL11A-2645 − AAACGGAAACAAUGCAA 17 3130 BCL11A-2646 − AAACUUCUGCACUGGAG 17 3131 BCL11A-2647 + AAAUAAGAAUGUCCCCCAAU 20 3132 BCL11A-2648 − AACCCCAGCACUUAAGCAAA 20 3133 BCL11A-2649 + AAGAAUGGCUUCAAGAGGCU 20 3134 BCL11A-2650 + AAUGGCUUCAAGAGGCU 17 3135 BCL11A-2651 − ACAGAUGAUGAACCAGACCA 20 3136 BCL11A-2652 − ACCAGACCACGGCCCGU 17 3137 BCL11A-2653 − ACCCCAGCACUUAAGCAAAC 20 3138 BCL11A-2654 + ACCUGGAUGCCAACCUCCAC 20 3139 BCL11A-2655 + ACUGCCCACAGGUGAGG 17 3140 BCL11A-2656 + AGAGCUCCAUGUGCAGAACG 20 3141 BCL11A-2657 − AGAUGAACUUCCCAUUG 17 3142 BCL11A-2658 + AGCUCCAUGUGCAGAACGAG 20 3143 BCL11A-2659 − AGGAAUUUGCCCCAAAC 17 3144 BCL11A-2660 + AGGAGGUCAUGAUCCCCUUC 20 3145 BCL11A-2661 + AGGUCAUGAUCCCCUUC 17 3146 BCL11A-2662 − AUAAACUUCUGCACUGG 17 3147 BCL11A-2663 + AUAAGAAUGUCCCCCAA 17 3148 BCL11A-2664 − AUCAUGACCUCCUCACCUGU 20 3149 BCL11A-2665 + AUCUCGAUUGGUGAAGGGGA 20 3150 BCL11A-2666 − AUGACCUCCUCACCUGU 17 3151 BCL11A-2667 + AUGUGCAGAACGAGGGG 17 3152 BCL11A-2668 + AUUGGUGAAGGGGAAGG 17 3153 BCL11A-2669 − CACAAACGGAAACAAUGCAA 20 3154 BCL11A-2670 + CACUCAUCCCAGGCGUG 17 3155 BCL11A-2671 + CAGAACGAGGGGAGGAG 17 3156 BCL11A-2672 − CAGAUGAACUUCCCAUU 17 3157 BCL11A-2673 + CAGCUUUUUCUAAGCAG 17 3158 BCL11A-2674 − CAUCCAGGUCACGCCAG 17 3159 BCL11A-2675 + CAUCUCGAUUGGUGAAG 17 3160 BCL11A-2676 + CAUCUGGCACUGCCCAC 17 3161 BCL11A-2677 − CAUGACCUCCUCACCUG 17 3162 BCL11A-2678 + CCAAUGGGAAGUUCAUC 17 3163 BCL11A-2679 + CCACAGCUUUUUCUAAGCAG 20 3164 BCL11A-2680 − CCAGACCACGGCCCGUU 17 3165 BCL11A-2681 − CCAGAUGAACUUCCCAU 17 3166 BCL11A-2682 − CCAGAUGAACUUCCCAUUGG 20 3167 BCL11A-2683 − CCAGCACUUAAGCAAAC 17 3168 BCL11A-2684 − CCCAGCACUUAAGCAAA 17 3169 BCL11A-2685 + CCCCUUCUGGAGCUCCCAAC 20 3170 BCL11A-2686 − CCCGUUGGGAGCUCCAGAAG 20 3171 BCL11A-2687 − CCGUUGGGAGCUCCAGA 17 3172 BCL11A-2688 + CCGUUUGCUUAAGUGCU 17 3173 BCL11A-2689 − CCUCUGCUUAGAAAAAGCUG 20 3174 BCL11A-2690 + CCUUCUGGAGCUCCCAA 17 3175 BCL11A-2691 − CGUGGAGGUUGGCAUCC 17 3176 BCL11A-2692 − CGUUGGGAGCUCCAGAA 17 3177 BCL11A-2693 + CGUUUGCUUAAGUGCUG 17 3178 BCL11A-2694 + CUAUGUGUUCCUGUUUG 17 3179 BCL11A-2695 + CUCCAUGUGCAGAACGA 17 3180 BCL11A-2696 − CUCUAAUCCCCACGCCU 17 3181 BCL11A-2697 + CUGCACUCAUCCCAGGCGUG 20 3182 BCL11A-2698 + CUGCUAUGUGUUCCUGUUUG 20 3183 BCL11A-2699 − CUGCUUAGAAAAAGCUG 17 3184 BCL11A-2700 + CUGGAGCUCCCAACGGGCCG 20 3185 BCL11A-2701 + CUGGAUGCCAACCUCCA 17 3186 BCL11A-2702 + CUUCUGGAGCUCCCAAC 17 3187 BCL11A-2703 − UAAACUUCUGCACUGGA 17 3188 BCL11A-2704 + UAAGAAUGUCCCCCAAU 17 3189 BCL11A-2705 − UAGAGGAAUUUGCCCCAAAC 20 3190 BCL11A-2706 + UAUUCUGCACUCAUCCC 17 3191 BCL11A-2707 + UCCAUGUGCAGAACGAG 17 3192 BCL11A-2708 + UCCAUGUGCAGAACGAGGGG 20 3193 BCL11A-2709 − UCCCCUCGUUCUGCACA 17 3194 BCL11A-2710 + UCCCCUUCUGGAGCUCCCAA 20 3195 BCL11A-2711 − UCCCGUGGAGGUUGGCAUCC 20 3196 BCL11A-2712 − UCCUCCCCUCGUUCUGCACA 20 3197 BCL11A-2713 + UCGAUUGGUGAAGGGGA 17 3198 BCL11A-2714 + UCGAUUGGUGAAGGGGAAGG 20 3199 BCL11A-2715 + UCUGCACUCAUCCCAGGCGU 20 3200 BCL11A-2716 + UCUGGCACUGCCCACAGGUG 20 3201 BCL11A-2717 + UCUGUAAGAAUGGCUUCAAG 20 3202 BCL11A-2718 + UGCACUCAUCCCAGGCG 17 3203 BCL11A-2719 − UGCCAGAUGAACUUCCCAUU 20 3204 BCL11A-2720 + UGCUAUGUGUUCCUGUU 17 3205 BCL11A-2721 + UGGAUGCCAACCUCCAC 17 3206 BCL11A-2722 + UGGUUCAUCAUCUGUAAGAA 20 3207 BCL11A-2723 − UGUUUAUCAACGUCAUCUAG 20 3208 BCL11A-2724 − UUAUUUUUAUCGAGCACAAA 20 3209 BCL11A-2725 + UUCAUCAUCUGUAAGAA 17 3210 BCL11A-2726 + UUCCCGUUUGCUUAAGUGCU 20 3211 BCL11A-2727 + UUCUGCACUCAUCCCAGGCG 20 3212 BCL11A-2728 + UUUCAUCUCGAUUGGUGAAG 20 3213 BCL11A-2729 + UUUUCAUCUCGAUUGGUGAA 20 3214 BCL11A-2730 − UUUUUAUCGAGCACAAA 17 3215 BCL11A-2731 + UUUUUCAUCUCGAUUGGUGA 20 3216

Table 4E provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to fifth tier parameters. The targeting domains outside the first 500 bp of coding sequence downstream of start codon. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL23A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL3A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 4E 5th Tier Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO BCL11A-2732 + UAUGCGGUCCGACUCGC 17 3217 BCL11A-2733 − UCGGACCGCAUAGACGA 17 3218 BCL11A-2734 + UGGGUACUACGCCGAAU 17 3219 BCL11A-2735 + GGUACUACGCCGAAUGG 17 3220 BCL11A-2736 − UUGCGACGAAGACUCGG 17 3221 BCL11A-2737 + CUGGGUACUACGCCGAA 17 3222 BCL11A-2738 + GGGUACUACGCCGAAUG 17 3223 BCL11A-2739 + UCGGACUUGACCGUCAU 17 3224 BCL11A-2740 + AGGGAUACCAACCCGCG 17 3225 BCL11A-2741 − CGCGCUCAAGUCCGUGG 17 3226 BCL11A-2742 + CGAGGAGUGCUCCGACG 17 3227 BCL11A-2743 + GUCGGACUUGACCGUCA 17 3228 BCL11A-2744 + UGCACGCGUGGUCGCAC 17 3229 BCL11A-2745 − CAGCGCGCUCAAGUCCG 17 3230 BCL11A-2746 + UACCAACCCGCGGGGUC 17 3231 BCL11A-2747 − GUGGCUCGCCGGCUACG 17 3232 BCL11A-2748 + CGGACUUGACCGUCAUG 17 3233 BCL11A-2749 − CACCGCAUAGAGCGCCU 17 3234 BCL11A-2750 − GCGCAUCAAGCUCGAGA 17 3235 BCL11A-2751 + GGCCCGGACCACUAAUA 17 3236 BCL11A-2752 + GCCCGGACCACUAAUAU 17 3237 BCL11A-2753 − GCAUAAGCGCGGCCACC 17 3238 BCL11A-2754 + AGGCGCUCUAUGCGGUG 17 3239 BCL11A-2755 − ACGGUCAAGUCCGACGA 17 3240 BCL11A-2756 + CGAGGCCGACUCGCCCG 17 3241 BCL11A-2757 − ACCGCAUAGAGCGCCUG 17 3242 BCL11A-2758 − CGACCACGCGUGCACCC 17 3243 BCL11A-2759 + GUACACGUUCUCCGUGU 17 3244 BCL11A-2760 − CACUUGCGACGAAGACU 17 3245 BCL11A-2761 − CGGGUUGGUAUCCCUUC 17 3246 BCL11A-2762 − CUCGUCGGAGCACUCCU 17 3247 BCL11A-2763 + CCCGGACCACUAAUAUG 17 3248 BCL11A-2764 + UCGGUGGUGGACUAAAC 17 3249 BCL11A-2765 + CAGGCGCUCUAUGCGGU 17 3250 BCL11A-2766 + AAGGGAUACCAACCCGC 17 3251 BCL11A-2767 + GGCGCUCUAUGCGGUGG 17 3252 BCL11A-2768 − CCACCGCAUAGAGCGCC 17 3253 BCL11A-2769 − UACUCGCAGUGGCUCGC 17 3254 BCL11A-2770 − CGGGCGAGUCGGCCUCG 17 3255 BCL11A-2771 + UACACGUUCUCCGUGUU 17 3256 BCL11A-2772 − AGCACGCCCCAUAUUAG 17 3257 BCL11A-2773 + GAAGGGAUACCAACCCG 17 3258 BCL11A-2774 + UUGGGCAUCGCGGCCGG 17 3259 BCL11A-2775 − CCGGGCGAGUCGGCCUC 17 3260 BCL11A-2776 + GGUGGAGAGACCGUCGU 17 3261 BCL11A-2777 + GUUGGGCAUCGCGGCCG 17 3262 BCL11A-2778 − AGAACGUGUACUCGCAG 17 3263 BCL11A-2779 + ACCAACCCGCGGGGUCA 17 3264 BCL11A-2780 − CACGAGAACAGCUCGCG 17 3265 BCL11A-2781 − UAUUAGUGGUCCGGGCC 17 3266 BCL11A-2782 + CGUCGCAAGUGUCCCUG 17 3267 BCL11A-2783 + CCCGCGAGCUGUUCUCG 17 3268 BCL11A-2784 + UGCGCCGGUGCACCACC 17 3269 BCL11A-2785 − CUGCCCGACGUCAUGCA 17 3270 BCL11A-2786 − GACGAAGACUCGGUGGC 17 3271 BCL11A-2787 − CCUGCCCGACGUCAUGC 17 3272 BCL11A-2788 + AAGGGCGGCUUGCUACC 17 3273 BCL11A-2789 − GGGUGGACUACGGCUUC 17 3274 BCL11A-2790 + UCGCUGGUGCCGGGUUC 17 3275 BCL11A-2791 − GGCGAGAAGCAUAAGCG 17 3276 BCL11A-2792 + GGACUUGAGCGCGCUGC 17 3277 BCL11A-2793 − CUCGGUGGCCGGCGAGU 17 3278 BCL11A-2794 + CCCGAGGCCGACUCGCC 17 3279 BCL11A-2795 − CCCGGGCGAGUCGGCCU 17 3280 BCL11A-2796 − CCGCAUAGAGCGCCUGG 17 3281 BCL11A-2797 + UGUUGGGCAUCGCGGCC 17 3282 BCL11A-2798 + GUGUUGGGCAUCGCGGC 17 3283 BCL11A-2799 + UCUCUCGAUACUGAUCC 17 3284 BCL11A-2800 − ACCCGAGUGCCUUUGAC 17 3285 BCL11A-2801 + UCCGACGAGGAGGCAAA 17 3286 BCL11A-2802 − ACCCGGCACCAGCGACU 17 3287 BCL11A-2803 + CCCCGUUCUCCGGGAUC 17 3288 BCL11A-2804 + CCGAGGCCGACUCGCCC 17 3289 BCL11A-2805 − CCCCAUAUUAGUGGUCC 17 3290 BCL11A-2806 + GACUUGGACUUGACCGG 17 3291 BCL11A-2807 − GCCCCAUAUUAGUGGUC 17 3292 BCL11A-2808 − AGGGUGGACUACGGCUU 17 3293 BCL11A-2809 − CAAAUCGUCCCCCAUGA 17 3294 BCL11A-2810 − CGACGUCAUGCAGGGCA 17 3295 BCL11A-2811 − GGCCGCGAUGCCCAACA 17 3296 BCL11A-2812 + CCAGGCGCUCUAUGCGG 17 3297 BCL11A-2813 − CCUGAUCCCGGAGAACG 17 3298 BCL11A-2814 + CCAACCCGCGGGGUCAG 17 3299 BCL11A-2815 − GGCGAGUCGGCCUCGGG 17 3300 BCL11A-2816 + GGCAAAAGGCGAUUGUC 17 3301 BCL11A-2817 + UUUGGACAGGCCCCCCG 17 3302 BCL11A-2818 + GCGGCUUGCUACCUGGC 17 3303 BCL11A-2819 + GGACUUGACCGUCAUGG 17 3304 BCL11A-2820 + GGAGUGCUCCGACGAGG 17 3305 BCL11A-2821 − AUUAGUGGUCCGGGCCC 17 3306 BCL11A-2822 − CCACGAGAACAGCUCGC 17 3307 BCL11A-2823 − GUAUCGAGAGAGGCUUC 17 3308 BCL11A-2824 + CUCCGUGUUGGGCAUCG 17 3309 BCL11A-2825 + CAAACUCCCGUUCUCCG 17 3310 BCL11A-2826 − ACCUGAUCCCGGAGAAC 17 3311 BCL11A-2827 − GGCACUGUUAAUGGCCG 17 3312 BCL11A-2828 + UUCUCCGGGAUCAGGUU 17 3313 BCL11A-2829 − UAUGGAGCCUCCCGCCA 17 3314 BCL11A-2830 + CUUGAUGCGCUUAGAGA 17 3315 BCL11A-2831 − UAGCAAGCCGCCCUUCC 17 3316 BCL11A-2832 − CCGGCUACGCGGCCUCC 17 3317 BCL11A-2833 + UCCAAGUGAUGUCUCGG 17 3318 BCL11A-2834 − GAACAGCUCGCGGGGCG 17 3319 BCL11A-2835 − GCUGCGGUUGAAUCCAA 17 3320 BCL11A-2836 + UGACUUGGACUUGACCG 17 3321 BCL11A-2837 − CCCGGAGAACGGGGACG 17 3322 BCL11A-2838 + GUGGCGCUUCAGCUUGC 17 3323 BCL11A-2839 + GUUCUCCGGGAUCAGGU 17 3324 BCL11A-2840 + CAGUGCCAUCGUCUAUG 17 3325 BCL11A-2841 + UCUCCGGGAUCAGGUUG 17 3326 BCL11A-2842 − GACGAUGGCACUGUUAA 17 3327 BCL11A-2843 − CUGCUCCCCGGGCGAGU 17 3328 BCL11A-2844 + CGGUGGUGGACUAAACA 17 3329 BCL11A-2845 − CUCGCGGGGCGCGGUCG 17 3330 BCL11A-2846 + AUGCCCUGCAUGACGUC 17 3331 BCL11A-2847 + UGGACUUGACCGGGGGC 17 3332 BCL11A-2848 − ACCACCGAGACAUCACU 17 3333 BCL11A-2849 − GGAGUUCGACCUGCCCC 17 3334 BCL11A-2850 + CCUGCAUGACGUCGGGC 17 3335 BCL11A-2851 + CUGCAUGACGUCGGGCA 17 3336 BCL11A-2852 − AGGAUCAGUAUCGAGAG 17 3337 BCL11A-2853 + GGACUUGACCGGGGGCU 17 3338 BCL11A-2854 + AAAGGCACUCGGGUGAU 17 3339 BCL11A-2855 − UGGACGGAGGGAUCUCG 17 3340 BCL11A-2856 + CCCCCAGGCGCUCUAUG 17 3341 BCL11A-2857 − CCGCCAUGGAUUUCUCU 17 3342 BCL11A-2858 − GGCGCGGUCGUGGGCGU 17 3343 BCL11A-2859 − AACCUGAUCCCGGAGAA 17 3344 BCL11A-2860 + CAUGCCCUGCAUGACGU 17 3345 BCL11A-2861 + CGCUGGUGCCGGGUUCC 17 3346 BCL11A-2862 + CCUGGAGGCCGCGUAGC 17 3347 BCL11A-2863 − CCCCUGACCCCGCGGGU 17 3348 BCL11A-2864 + GCUUAUGCUUCUCGCCC 17 3349 BCL11A-2865 − AAGUCAUGCGAGUUCUG 17 3350 BCL11A-2866 + CACCAAGUCGCUGGUGC 17 3351 BCL11A-2867 − CCCGAGUGCCUUUGACA 17 3352 BCL11A-2868 + CAUGACUUGGACUUGAC 17 3353 BCL11A-2869 − CGACCCCAACCUGAUCC 17 3354 BCL11A-2870 + ACCAAGUCGCUGGUGCC 17 3355 BCL11A-2871 + AAGUGAUGUCUCGGUGG 17 3356 BCL11A-2872 − CUUCUCCACACCGCCCG 17 3357 BCL11A-2873 + UGGAGUCUCCGAAGCUA 17 3358 BCL11A-2874 − CGCUUCUCCACACCGCC 17 3359 BCL11A-2875 + GCUGGUGCCGGGUUCCG 17 3360 BCL11A-2876 − CGCAGCGGCACGGGAAG 17 3361 BCL11A-2877 + GCAUCGCGGCCGGGGGC 17 3362 BCL11A-2878 − GAGCACUCCUCGGAGAA 17 3363 BCL11A-2879 + GGGGGGCGUCGCCAGGA 17 3364 BCL11A-2880 + GAAAGCGCCCUUCUGCC 17 3365 BCL11A-2881 − CUGGACGGAGGGAUCUC 17 3366 BCL11A-2882 − CGGCUUCGGGCUGAGCC 17 3367 BCL11A-2883 + GGGGGCGUCGCCAGGAA 17 3368 BCL11A-2884 + UAACCUUUGCAUAGGGC 17 3369 BCL11A-2885 − GGGCGAGUCGGCCUCGG 17 3370 BCL11A-2886 − CACACCGCCCGGGGAGC 17 3371 BCL11A-2887 − GGGAUCUCGGGGCGCAG 17 3372 BCL11A-2888 + CUCGCUGAAGUGCUGCA 17 3373 BCL11A-2889 − UCGGGGCGCAGCGGCAC 17 3374 BCL11A-2890 − AAGUCCCCUGACCCCGC 17 3375 BCL11A-2891 − GCCUUUUGCCUCCUCGU 17 3376 BCL11A-2892 − CACCUGGCCGAGGCCGA 17 3377 BCL11A-2893 − GGUAUCCCUUCAGGACU 17 3378 BCL11A-2894 + GUGGUGGACUAAACAGG 17 3379 BCL11A-2895 + GCGAGCUGUUCUCGUGG 17 3380 BCL11A-2896 − AGCACUCCUCGGAGAAC 17 3381 BCL11A-2897 − CAUGCAGCACUUCAGCG 17 3382 BCL11A-2898 + UGGCCUGGGUGCACGCG 17 3383 BCL11A-2899 − AGCGAGAGGGUGGACUA 17 3384 BCL11A-2900 + GCACAGGUUGCACUUGU 17 3385 BCL11A-2901 + GAGAAAUCCAUGGCGGG 17 3386 BCL11A-2902 + GCAGAACUCGCAUGACU 17 3387 BCL11A-2903 + UCUCCGAAGCUAAGGAA 17 3388 BCL11A-2904 + UGACGUCGGGCAGGGCG 17 3389 BCL11A-2905 + GGGUCCAAGUGAUGUCU 17 3390 BCL11A-2906 − GCAACCUGGUGGUGCAC 17 3391 BCL11A-2907 + GGUGGCGCGCCGCCUCC 17 3392 BCL11A-2908 + GCUGCCCACCAAGUCGC 17 3393 BCL11A-2909 + GUUCUCGCUCUUGAACU 17 3394 BCL11A-2910 + CCGCAGCACCCUGUCAA 17 3395 BCL11A-2911 − GAAGUCCCCUGACCCCG 17 3396 BCL11A-2912 − GCGCGGCCACCUGGCCG 17 3397 BCL11A-2913 + GGCGUCGCCAGGAAGGG 17 3398 BCL11A-2914 − GUUGAAUCCAAUGGCUA 17 3399 BCL11A-2915 − CUCGGGGCGCAGCGGCA 17 3400 BCL11A-2916 − CCGAGGCCGAGGGCCAC 17 3401 BCL11A-2917 + CUAAACAGGGGGGGAGU 17 3402 BCL11A-2918 − GCGGCACGGGAAGUGGA 17 3403 BCL11A-2919 + CACAGGUUGCACUUGUA 17 3404 BCL11A-2920 − CAGCGAGGCCUUCCACC 17 3405 BCL11A-2921 − AACCUGCUAAGAAUACC 17 3406 BCL11A-2922 + AUCCUGGUAUUCUUAGC 17 3407 BCL11A-2923 + GGUGGUGGACUAAACAG 17 3408 BCL11A-2924 − CGAGGCCGAGGGCCACA 17 3409 BCL11A-2925 + GUACAUGUGUAGCUGCU 17 3410 BCL11A-2926 + UUGAUGCGCUUAGAGAA 17 3411 BCL11A-2927 + UCCUCGUCCCCGUUCUC 17 3412 BCL11A-2928 + AUGACUUGGACUUGACC 17 3413 BCL11A-2929 + GUCUCCGAAGCUAAGGA 17 3414 BCL11A-2930 + GGUGGACUAAACAGGGG 17 3415 BCL11A-2931 + GCAUGUGCGUCUUCAUG 17 3416 BCL11A-2932 + GGCACUCGGGUGAUGGG 17 3417 BCL11A-2933 + AUAGGGCUGGGCCGGCC 17 3418 BCL11A-2934 + CCGUCCAGCUCCCCGGG 17 3419 BCL11A-2935 + GCAGUAACCUUUGCAUA 17 3420 BCL11A-2936 − GAUCCCUUCCUUAGCUU 17 3421 BCL11A-2937 + AAGGGGCUCAGCGAGCU 17 3422 BCL11A-2938 − AGCUGACGGAGAGCGAG 17 3423 BCL11A-2939 − UCGCGGGGCGCGGUCGU 17 3424 BCL11A-2940 − AGCGGCACGGGAAGUGG 17 3425 BCL11A-2941 + CAAAGGCACUCGGGUGA 17 3426 BCL11A-2942 + CUGCACCUAGUCCUGAA 17 3427 BCL11A-2943 − GCUGGACGGAGGGAUCU 17 3428 BCL11A-2944 + CCCUGUCAAAGGCACUC 17 3429 BCL11A-2945 + AACCUUUGCAUAGGGCU 17 3430 BCL11A-2946 + CGCCCGGGGAGCAGCCG 17 3431 BCL11A-2947 + UGGUGGACUAAACAGGG 17 3432 BCL11A-2948 − GGCCCAGCCCUAUGCAA 17 3433 BCL11A-2949 + CCUCGUCCCCGUUCUCC 17 3434 BCL11A-2950 − GCCAGCUCCCCGGAACC 17 3435 BCL11A-2951 + GCCGGGUUCCGGGGAGC 17 3436 BCL11A-2952 + UGCAGUAACCUUUGCAU 17 3437 BCL11A-2953 + GCUUCUCGCCCAGGACC 17 3438 BCL11A-2954 − CCGCCCGGGGAGCUGGA 17 3439 BCL11A-2955 − CCGGGGAGCUGGACGGA 17 3440 BCL11A-2956 − CUUCCGGCCUGGCAGAA 17 3441 BCL11A-2957 + CCUAGAGAAAUCCAUGG 17 3442 BCL11A-2958 + GGAGGGGGGGCGUCGCC 17 3443 BCL11A-2959 − UACUUAGAAAGCGAACA 17 3444 BCL11A-2960 + GGAGGCUCCAUAGCCAU 17 3445 BCL11A-2961 + ACACAUCUUGAGCUCUC 17 3446 BCL11A-2962 − GGCACCAGCGACUUGGU 17 3447 BCL11A-2963 + GGGAUCUUUGAGCUGCC 17 3448 BCL11A-2964 + GCAGCAGCUUUUUGGAC 17 3449 BCL11A-2965 + CUGCAAUAUGAAUCCCA 17 3450 BCL11A-2966 + UCUGCACCUAGUCCUGA 17 3451 BCL11A-2967 + GAAGGGGCUCAGCGAGC 17 3452 BCL11A-2968 + UUCCGGGGAGCUGGCGG 17 3453 BCL11A-2969 − GCACCGGCGCAGCCACA 17 3454 BCL11A-2970 + AUAUGAAUCCCAUGGAG 17 3455 BCL11A-2971 − GUGGUCCGGGCCCGGGC 17 3456 BCL11A-2972 − CUUCACACACCCCCAUU 17 3457 BCL11A-2973 − GUCCAAAAAGCUGCUGC 17 3458 BCL11A-2974 − CGGCACCAGCGACUUGG 17 3459 BCL11A-2975 − GCUUCUCCACACCGCCC 17 3460 BCL11A-2976 + CGCCCGUGUGGCUGCGC 17 3461 BCL11A-2977 − CACGCACAGAACACUCA 17 3462 BCL11A-2978 + UGUACAUGUGUAGCUGC 17 3463 BCL11A-2979 − CACCGGCGCAGCCACAC 17 3464 BCL11A-2980 + UUGCUACCUGGCUGGAA 17 3465 BCL11A-2981 + ACCCUGUCAAAGGCACU 17 3466 BCL11A-2982 − CCACCUGGCCGAGGCCG 17 3467 BCL11A-2983 + GGGCGGAUUGCAGAGGA 17 3468 BCL11A-2984 + CUAGAGAAAUCCAUGGC 17 3469 BCL11A-2985 − GGCGGAAGAGAUGGCCC 17 3470 BCL11A-2986 + GGGGCGGAUUGCAGAGG 17 3471 BCL11A-2987 − GUGUGGCAGUUUUCGGA 17 3472 BCL11A-2988 − GAGAGAGGCUUCCGGCC 17 3473 BCL11A-2989 + CGGGUGAUGGGUGGCCA 17 3474 BCL11A-2990 − CCCGGGGAGCUGGACGG 17 3475 BCL11A-2991 − UAGGAGACUUAGAGAGC 17 3476 BCL11A-2992 + CACAUCUUGAGCUCUCU 17 3477 BCL11A-2993 + CCUCGGCCUCGGCCAGG 17 3478 BCL11A-2994 − GGCCUUCCACCAGGUCC 17 3479 BCL11A-2995 + UCUCGCCCAGGACCUGG 17 3480 BCL11A-2996 + UCUGCCCUCUUUUGAGC 17 3481 BCL11A-2997 + ACUAAACAGGGGGGGAG 17 3482 BCL11A-2998 + CUUGACCGGGGGCUGGG 17 3483 BCL11A-2999 + UUGACCGGGGGCUGGGA 17 3484 BCL11A-3000 − AGACUUAGAGAGCUGGC 17 3485 BCL11A-3001 − AGCCCACCGCUGUCCCC 17 3486 BCL11A-3002 − AGCCAUUCACCAGUGCA 17 3487 BCL11A-3003 − GCUUCCGGCCUGGCAGA 17 3488 BCL11A-3004 − GACUUAGAGAGCUGGCA 17 3489 BCL11A-3005 − AGGCCCAGCUCAAAAGA 17 3490 BCL11A-3006 + UCGGGUGAUGGGUGGCC 17 3491 BCL11A-3007 + CAAGAGAAACCAUGCAC 17 3492 BCL11A-3008 + AUCUUUGAGCUGCCUGG 17 3493 BCL11A-3009 + UAUUCUUAGCAGGUUAA 17 3494 BCL11A-3010 + CUGCCCUCUUUUGAGCU 17 3495 BCL11A-3011 + CCAUCUCUUCCGCCCCC 17 3496 BCL11A-3012 − UGGCCGCGGCUGCUCCC 17 3497 BCL11A-3013 + CCUGUGGCCCUCGGCCU 17 3498 BCL11A-3014 + CAGCUCCCCGGGCGGUG 17 3499 BCL11A-3015 + UUUGCAUAGGGCUGGGC 17 3500 BCL11A-3016 + GGCCCUCGGCCUCGGCC 17 3501 BCL11A-3017 − GCUGACGGAGAGCGAGA 17 3502 BCL11A-3018 − AGAUGUGUGGCAGUUUU 17 3503 BCL11A-3019 + AUUCUUAGCAGGUUAAA 17 3504 BCL11A-3020 + UCUCCUAGAGAAAUCCA 17 3505 BCL11A-3021 − CCUUUGACAGGGUGCUG 17 3506 BCL11A-3022 + GGAGGGGCGGAUUGCAG 17 3507 BCL11A-3023 + UUCUUAGCAGGUUAAAG 17 3508 BCL11A-3024 + CGGAUUGCAGAGGAGGG 17 3509 BCL11A-3025 + UUUGAGCUGGGCCUGCC 17 3510 BCL11A-3026 + CUUCAGCUUGCUGGCCU 17 3511 BCL11A-3027 + CUUGAACUUGGCCACCA 17 3512 BCL11A-3028 − CUGCAACCAUUCCAGCC 17 3513 BCL11A-3029 − CAUAGAGCGCCUGGGGG 17 3514 BCL11A-3030 − GGGCGCGGUCGUGGGCG 17 3515 BCL11A-3031 + UCCCAUGGAGAGGUGGC 17 3516 BCL11A-3032 − GGCCGCGGCUGCUCCCC 17 3517 BCL11A-3033 − AUUUCAGAGCAACCUGG 17 3518 BCL11A-3034 − GCCUUCCACCAGGUCCU 17 3519 BCL11A-3035 + UGAAUCCCAUGGAGAGG 17 3520 BCL11A-3036 + UUGAGCUGGGCCUGCCC 17 3521 BCL11A-3037 + AGGGGCUCAGCGAGCUG 17 3522 BCL11A-3038 + AGGGCUUCUCGCCCGUG 17 3523 BCL11A-3039 − CACCGCUGUCCCCAGGC 17 3524 BCL11A-3040 − CAAAUUUCAGAGCAACC 17 3525 BCL11A-3041 − AGAGAGCUCAAGAUGUG 17 3526 BCL11A-3042 + AACCAUGCACUGGUGAA 17 3527 BCL11A-3043 + CCUCCGUCCAGCUCCCC 17 3528 BCL11A-3044 + AGUGUCCCUGUGGCCCU 17 3529 BCL11A-3045 + CCCUCCGUCCAGCUCCC 17 3530 BCL11A-3046 + GGCCUGGGGACAGCGGU 17 3531 BCL11A-3047 + GCCCAGCAGCAGCUUUU 17 3532 BCL11A-3048 − CAGGCCCAGCUCAAAAG 17 3533 BCL11A-3049 − CUUCGGGCUGAGCCUGG 17 3534 BCL11A-3050 + CCCAUGGAGAGGUGGCU 17 3535 BCL11A-3051 − CCCAGCCACCUCUCCAU 17 3536 BCL11A-3052 + GGGUUCCGGGGAGCUGG 17 3537 BCL11A-3053 + UAGGGCUGGGCCGGCCU 17 3538 BCL11A-3054 − CCUGGGGGCGGAAGAGA 17 3539 BCL11A-3055 + GCCCAGGACCUGGUGGA 17 3540 BCL11A-3056 − CGGGCUGAGCCUGGAGG 17 3541 BCL11A-3057 − ACCACGAGAACAGCUCG 17 3542 BCL11A-3058 + CGGCCUGGGGACAGCGG 17 3543 BCL11A-3059 − UCCAAAAAGCUGCUGCU 17 3544 BCL11A-3060 + GCGCCCUUCUGCCAGGC 17 3545 BCL11A-3061 − UCCCAGCCACCUCUCCA 17 3546 BCL11A-3062 − CUCCACCGCCAGCUCCC 17 3547 BCL11A-3063 + CUGGGCCUGCCCGGGCC 17 3548 BCL11A-3064 + AGGGCUGGGCCGGCCUG 17 3549 BCL11A-3065 + AACAGGGGGGGAGUGGG 17 3550 BCL11A-3066 − GGAGAACGGGGACGAGG 17 3551 BCL11A-3067 + UGAUGCGCUUAGAGAAG 17 3552 BCL11A-3068 + GGAUUGCAGAGGAGGGA 17 3553 BCL11A-3069 + GGCCGGCCUGGGGACAG 17 3554 BCL11A-3070 + GAUUGCAGAGGAGGGAG 17 3555 BCL11A-3071 + AUUGCAGAGGAGGGAGG 17 3556 BCL11A-3072 + ACCGGGGGCUGGGAGGG 17 3557 BCL11A-3073 + UGGAGAGGUGGCUGGGA 17 3558 BCL11A-3074 + UUGCAGAGGAGGGAGGG 17 3559 BCL11A-3075 − CGGGGACGAGGAGGAAG 17 3560 BCL11A-3076 − GACGGAGAGCGAGAGGG 17 3561 BCL11A-3077 − UCCUCCCUCCCAGCCCC 17 3562 BCL11A-3078 + GCUUCAGCUUGCUGGCC 17 3563 BCL11A-3079 + UGCAGAGGAGGGAGGGG 17 3564 BCL11A-3080 + GGGCUGGGAGGGAGGAG 17 3565 BCL11A-3081 − GGAAGAGGAGGACGACG 17 3566 BCL11A-3082 + GGGGCUGGGAGGGAGGA 17 3567 BCL11A-3083 − GGAGGACGACGAGGAAG 17 3568 BCL11A-3084 − GGAGGAGGAGGAGCUGA 17 3569 BCL11A-3085 + GGGGGCUGGGAGGGAGG 17 3570 BCL11A-3086 + CUGGGAGGGAGGAGGGG 17 3571 BCL11A-3087 − CGAGGAAGAGGAAGAAG 17 3572 BCL11A-3088 − GGACGAGGAGGAAGAGG 17 3573 BCL11A-3089 − GGAAGAAGAGGAGGAAG 17 3574 BCL11A-3090 − GGAAGAGGAAGAAGAGG 17 3575 BCL11A-3091 − AGAAGAGGAGGAAGAGG 17 3576 BCL11A-3092 − AGAGGAGGAAGAGGAGG 17 3577 BCL11A-3093 − GGAGGAAGAGGAGGAGG 17 3578 BCL11A-3094 + GUCUAUGCGGUCCGACUCGC 20 3579 BCL11A-3095 + UCGUCGGACUUGACCGUCAU 20 3580 BCL11A-3096 + CGUCGGACUUGACCGUCAUG 20 3581 BCL11A-3097 − AUGACGGUCAAGUCCGACGA 20 3582 BCL11A-3098 − GAGUCGGACCGCAUAGACGA 20 3583 BCL11A-3099 + CGGGCCCGGACCACUAAUAU 20 3584 BCL11A-3100 + GUCGUCGGACUUGACCGUCA 20 3585 BCL11A-3101 + CUCUGGGUACUACGCCGAAU 20 3586 BCL11A-3102 + CUGGGUACUACGCCGAAUGG 20 3587 BCL11A-3103 + CCGGGCCCGGACCACUAAUA 20 3588 BCL11A-3104 − CCGCGGGUUGGUAUCCCUUC 20 3589 BCL11A-3105 + UCUGGGUACUACGCCGAAUG 20 3590 BCL11A-3106 + GGAUACCAACCCGCGGGGUC 20 3591 BCL11A-3107 − ACGCCCCAUAUUAGUGGUCC 20 3592 BCL11A-3108 − CACUUGCGACGAAGACUCGG 20 3593 BCL11A-3109 + UCUCUGGGUACUACGCCGAA 20 3594 BCL11A-3110 − UAAGCGCAUCAAGCUCGAGA 20 3595 BCL11A-3111 − UGCGACGAAGACUCGGUGGC 20 3596 BCL11A-3112 + CGCGCUUAUGCUUCUCGCCC 20 3597 BCL11A-3113 + UGAAGGGAUACCAACCCGCG 20 3598 BCL11A-3114 + GGGCCCGGACCACUAAUAUG 20 3599 BCL11A-3115 + CGUGUUGGGCAUCGCGGCCG 20 3600 BCL11A-3116 + UCCGUGUUGGGCAUCGCGGC 20 3601 BCL11A-3117 + GUCGGACUUGACCGUCAUGG 20 3602 BCL11A-3118 + GCGCAAACUCCCGUUCUCCG 20 3603 BCL11A-3119 + CUCCGAGGAGUGCUCCGACG 20 3604 BCL11A-3120 + CACGGACUUGAGCGCGCUGC 20 3605 BCL11A-3121 − CACGCCCCAUAUUAGUGGUC 20 3606 BCL11A-3122 + GAUACCAACCCGCGGGGUCA 20 3607 BCL11A-3123 − CAGCGCGCUCAAGUCCGUGG 20 3608 BCL11A-3124 + GGGUGCACGCGUGGUCGCAC 20 3609 BCL11A-3125 − GAAGCAUAAGCGCGGCCACC 20 3610 BCL11A-3126 − GUGCGACCACGCGUGCACCC 20 3611 BCL11A-3127 + GAGUACACGUUCUCCGUGUU 20 3612 BCL11A-3128 + GUCUCGGUGGUGGACUAAAC 20 3613 BCL11A-3129 + CCGUUCUCCGGGAUCAGGUU 20 3614 BCL11A-3130 + CGAGUACACGUUCUCCGUGU 20 3615 BCL11A-3131 − CGGAGAACGUGUACUCGCAG 20 3616 BCL11A-3132 − GGGAGCACGCCCCAUAUUAG 20 3617 BCL11A-3133 − CCAUAUUAGUGGUCCGGGCC 20 3618 BCL11A-3134 + GCCGCAGAACUCGCAUGACU 20 3619 BCL11A-3135 + CGCCCCGCGAGCUGUUCUCG 20 3620 BCL11A-3136 − GCAGUGGCUCGCCGGCUACG 20 3621 BCL11A-3137 − CAUAUUAGUGGUCCGGGCCC 20 3622 BCL11A-3138 + CUGAAGGGAUACCAACCCGC 20 3623 BCL11A-3139 + AUACCAACCCGCGGGGUCAG 20 3624 BCL11A-3140 − CAGCAGCGCGCUCAAGUCCG 20 3625 BCL11A-3141 + CGUCCCCGUUCUCCGGGAUC 20 3626 BCL11A-3142 − CACCACGAGAACAGCUCGCG 20 3627 BCL11A-3143 − GCGGUUGAAUCCAAUGGCUA 20 3628 BCL11A-3144 − GGACACUUGCGACGAAGACU 20 3629 BCL11A-3145 + GUGUUGGGCAUCGCGGCCGG 20 3630 BCL11A-3146 + CUUCGUCGCAAGUGUCCCUG 20 3631 BCL11A-3147 + CCCCAGGCGCUCUAUGCGGU 20 3632 BCL11A-3148 + CCGUGUUGGGCAUCGCGGCC 20 3633 BCL11A-3149 + CGUUCUCCGGGAUCAGGUUG 20 3634 BCL11A-3150 + GCCUCUCUCGAUACUGAUCC 20 3635 BCL11A-3151 + UCGCAUGACUUGGACUUGAC 20 3636 BCL11A-3152 − AUCACCCGAGUGCCUUUGAC 20 3637 BCL11A-3153 − UAAGCGCGGCCACCUGGCCG 20 3638 BCL11A-3154 − GCACAAAUCGUCCCCCAUGA 20 3639 BCL11A-3155 − CGCCCUGCCCGACGUCAUGC 20 3640 BCL11A-3156 − CAACCUGAUCCCGGAGAACG 20 3641 BCL11A-3157 − CGGAGCACUCCUCGGAGAAC 20 3642 BCL11A-3158 − AGACUCGGUGGCCGGCGAGU 20 3643 BCL11A-3159 + GGCGGUGGAGAGACCGUCGU 20 3644 BCL11A-3160 − GUGUACUCGCAGUGGCUCGC 20 3645 BCL11A-3161 − UCGGAGCACUCCUCGGAGAA 20 3646 BCL11A-3162 − CCCGGCCGCGAUGCCCAACA 20 3647 BCL11A-3163 + CCCGUUCUCCGGGAUCAGGU 20 3648 BCL11A-3164 + UCGGUGGUGGACUAAACAGG 20 3649 BCL11A-3165 + CCUGAAGGGAUACCAACCCG 20 3650 BCL11A-3166 + GUCGUUCUCGCUCUUGAACU 20 3651 BCL11A-3167 − CCCCACCGCAUAGAGCGCCU 20 3652 BCL11A-3168 + GUCGCUGGUGCCGGGUUCCG 20 3653 BCL11A-3169 − CGAGAACAGCUCGCGGGGCG 20 3654 BCL11A-3170 + CGCAUGACUUGGACUUGACC 20 3655 BCL11A-3171 − CCCACCGCAUAGAGCGCCUG 20 3656 BCL11A-3172 + AAGUCGCUGGUGCCGGGUUC 20 3657 BCL11A-3173 + CGAGGAGUGCUCCGACGAGG 20 3658 BCL11A-3174 − UCCCCGGGCGAGUCGGCCUC 20 3659 BCL11A-3175 − CUCCCCGGGCGAGUCGGCCU 20 3660 BCL11A-3176 + CAUGACUUGGACUUGACCGG 20 3661 BCL11A-3177 − AGCUCGCGGGGCGCGGUCGU 20 3662 BCL11A-3178 + UGCUCCGACGAGGAGGCAAA 20 3663 BCL11A-3179 + CUUUUUGGACAGGCCCCCCG 20 3664 BCL11A-3180 − CUACGGCUUCGGGCUGAGCC 20 3665 BCL11A-3181 − CCCCGGGCGAGUCGGCCUCG 20 3666 BCL11A-3182 + UAACAGUGCCAUCGUCUAUG 20 3667 BCL11A-3183 − CUCCUCGUCGGAGCACUCCU 20 3668 BCL11A-3184 − CCCGGCACCAGCGACUUGGU 20 3669 BCL11A-3185 − GCGCUUCUCCACACCGCCCG 20 3670 BCL11A-3186 + CUCGGUGGUGGACUAAACAG 20 3671 BCL11A-3187 − CCCCCACCGCAUAGAGCGCC 20 3672 BCL11A-3188 − GAUCCCGGAGAACGGGGACG 20 3673 BCL11A-3189 + CCAGGCGCUCUAUGCGGUGG 20 3674 BCL11A-3190 − UUAGUGGUCCGGGCCCGGGC 20 3675 BCL11A-3191 + CCCAGGCGCUCUAUGCGGUG 20 3676 BCL11A-3192 − CGGCUGCUCCCCGGGCGAGU 20 3677 BCL11A-3193 − UCGCCGGCUACGCGGCCUCC 20 3678 BCL11A-3194 − AUCGAGAGAGGCUUCCGGCC 20 3679 BCL11A-3195 + GGGUCCAAGUGAUGUCUCGG 20 3680 BCL11A-3196 − AUCGCCUUUUGCCUCCUCGU 20 3681 BCL11A-3197 − AUCUCGGGGCGCAGCGGCAC 20 3682 BCL11A-3198 + CGGUGGUGGACUAAACAGGG 20 3683 BCL11A-3199 − GAUGGCACUGUUAAUGGCCG 20 3684 BCL11A-3200 + UGCCCUGCAUGACGUCGGGC 20 3685 BCL11A-3201 + UCUCGGUGGUGGACUAAACA 20 3686 BCL11A-3202 − AGAGGGUGGACUACGGCUUC 20 3687 BCL11A-3203 + CCCCGAGGCCGACUCGCCCG 20 3688 BCL11A-3204 − GAUCUCGGGGCGCAGCGGCA 20 3689 BCL11A-3205 − ACGGAAGUCCCCUGACCCCG 20 3690 BCL11A-3206 + ACUCGCCCGGGGAGCAGCCG 20 3691 BCL11A-3207 − UUGCGCUUCUCCACACCGCC 20 3692 BCL11A-3208 − GGAACCCGGCACCAGCGACU 20 3693 BCL11A-3209 + GCAUGACUUGGACUUGACCG 20 3694 BCL11A-3210 − UAAUGGCCGCGGCUGCUCCC 20 3695 BCL11A-3211 − CCGGGCGAGUCGGCCUCGGG 20 3696 BCL11A-3212 + GUCAAAGGCACUCGGGUGAU 20 3697 BCL11A-3213 − GGUGCUGCGGUUGAAUCCAA 20 3698 BCL11A-3214 − CUGGGCGAGAAGCAUAAGCG 20 3699 BCL11A-3215 + ACUUGGACUUGACCGGGGGC 20 3700 BCL11A-3216 + CCCCCCGAGGCCGACUCGCC 20 3701 BCL11A-3217 − CCACCGCAUAGAGCGCCUGG 20 3702 BCL11A-3218 + AGUCGCUGGUGCCGGGUUCC 20 3703 BCL11A-3219 + UCGCACAGGUUGCACUUGUA 20 3704 BCL11A-3220 + GCCCUGCAUGACGUCGGGCA 20 3705 BCL11A-3221 + CCGCCCCCAGGCGCUCUAUG 20 3706 BCL11A-3222 − GCCCUGCCCGACGUCAUGCA 20 3707 BCL11A-3223 + GUCGCACAGGUUGCACUUGU 20 3708 BCL11A-3224 − AGGUAGCAAGCCGCCCUUCC 20 3709 BCL11A-3225 − CCAACCUGAUCCCGGAGAAC 20 3710 BCL11A-3226 + AGGAAGGGCGGCUUGCUACC 20 3711 BCL11A-3227 − GAAGGAGUUCGACCUGCCCC 20 3712 BCL11A-3228 + CUUGGACUUGACCGGGGGCU 20 3713 BCL11A-3229 − GAGAGGGUGGACUACGGCUU 20 3714 BCL11A-3230 − UCCAAGUCAUGCGAGUUCUG 20 3715 BCL11A-3231 − ACCCGGCACCAGCGACUUGG 20 3716 BCL11A-3232 + CCCCCAGGCGCUCUAUGCGG 20 3717 BCL11A-3233 + GCGUCUGCCCUCUUUUGAGC 20 3718 BCL11A-3234 − GCCCGACGUCAUGCAGGGCA 20 3719 BCL11A-3235 + GAGCUUGAUGCGCUUAGAGA 20 3720 BCL11A-3236 − CAGCUCGCGGGGCGCGGUCG 20 3721 BCL11A-3237 + CGUGGUGGCGCGCCGCCUCC 20 3722 BCL11A-3238 − UCACCCGAGUGCCUUUGACA 20 3723 BCL11A-3239 − GAACGACCCCAACCUGAUCC 20 3724 BCL11A-3240 + CAACCGCAGCACCCUGUCAA 20 3725 BCL11A-3241 + UCCAAGUGAUGUCUCGGUGG 20 3726 BCL11A-3242 + GUUCUCCGUGUUGGGCAUCG 20 3727 BCL11A-3243 − CGGAAGUCCCCUGACCCCGC 20 3728 BCL11A-3244 + UAUGCUUCUCGCCCAGGACC 20 3729 BCL11A-3245 − AGCUGGACGGAGGGAUCUCG 20 3730 BCL11A-3246 + GGCUGCGCCGGUGCACCACC 20 3731 BCL11A-3247 − GUUGGUAUCCCUUCAGGACU 20 3732 BCL11A-3248 − AUAGACGAUGGCACUGUUAA 20 3733 BCL11A-3249 − CUCCCGCCAUGGAUUUCUCU 20 3734 BCL11A-3250 − ACCAGGAUCAGUAUCGAGAG 20 3735 BCL11A-3251 − AGUCCCCUGACCCCGCGGGU 20 3736 BCL11A-3252 + GUCUGGAGUCUCCGAAGCUA 20 3737 BCL11A-3253 − GCCGGCCCAGCCCUAUGCAA 20 3738 BCL11A-3254 − GAUGUGUGGCAGUUUUCGGA 20 3739 BCL11A-3255 + CUAGAGAAAUCCAUGGCGGG 20 3740 BCL11A-3256 + GGCGCUGCCCACCAAGUCGC 20 3741 BCL11A-3257 − CCCGGGCGAGUCGGCCUCGG 20 3742 BCL11A-3258 − ACACCGCCCGGGGAGCUGGA 20 3743 BCL11A-3259 + CAGUAACCUUUGCAUAGGGC 20 3744 BCL11A-3260 − UCAGUAUCGAGAGAGGCUUC 20 3745 BCL11A-3261 + GCAUGACGUCGGGCAGGGCG 20 3746 BCL11A-3262 − CCGCAUAGAGCGCCUGGGGG 20 3747 BCL11A-3263 + CCCCCGAGGCCGACUCGCCC 20 3748 BCL11A-3264 + AGGGCGGCUUGCUACCUGGC 20 3749 BCL11A-3265 + GCACCCUGUCAAAGGCACUC 20 3750 BCL11A-3266 + CUGAUCCUGGUAUUCUUAGC 20 3751 BCL11A-3267 + CAUGUGGCGCUUCAGCUUGC 20 3752 BCL11A-3268 + CCCACCAAGUCGCUGGUGCC 20 3753 BCL11A-3269 + GGAGGCAAAAGGCGAUUGUC 20 3754 BCL11A-3270 − CCCAACCUGAUCCCGGAGAA 20 3755 BCL11A-3271 + GAGUCUCCGAAGCUAAGGAA 20 3756 BCL11A-3272 − GGCUAUGGAGCCUCCCGCCA 20 3757 BCL11A-3273 + CGUCUGCCCUCUUUUGAGCU 20 3758 BCL11A-3274 − CGCCCGGGGAGCUGGACGGA 20 3759 BCL11A-3275 + AGUAACCUUUGCAUAGGGCU 20 3760 BCL11A-3276 − UCCACCACCGAGACAUCACU 20 3761 BCL11A-3277 + GGUUGCAGUAACCUUUGCAU 20 3762 BCL11A-3278 + GCAAUAUGAAUCCCAUGGAG 20 3763 BCL11A-3279 + ACCAUGCCCUGCAUGACGUC 20 3764 BCL11A-3280 + GGCCUCGCUGAAGUGCUGCA 20 3765 BCL11A-3281 − AGAGCAACCUGGUGGUGCAC 20 3766 BCL11A-3282 + GCCCACCAAGUCGCUGGUGC 20 3767 BCL11A-3283 + UGUCAAAGGCACUCGGGUGA 20 3768 BCL11A-3284 + AGCUUGAUGCGCUUAGAGAA 20 3769 BCL11A-3285 + AGGGGGGGCGUCGCCAGGAA 20 3770 BCL11A-3286 + GUGGAAAGCGCCCUUCUGCC 20 3771 BCL11A-3287 + UGGGGGUCCAAGUGAUGUCU 20 3772 BCL11A-3288 − CUCCAUGCAGCACUUCAGCG 20 3773 BCL11A-3289 + GCGCUUCAGCUUGCUGGCCU 20 3774 BCL11A-3290 − CUUCAGCGAGGCCUUCCACC 20 3775 BCL11A-3291 + GGAGUCUCCGAAGCUAAGGA 20 3776 BCL11A-3292 + CACUCGGGUGAUGGGUGGCC 20 3777 BCL11A-3293 − UGCGCUUCUCCACACCGCCC 20 3778 BCL11A-3294 + GGUGGUGGACUAAACAGGGG 20 3779 BCL11A-3295 − CGAGGCCUUCCACCAGGUCC 20 3780 BCL11A-3296 − AAUGGCCGCGGCUGCUCCCC 20 3781 BCL11A-3297 + GUUGUACAUGUGUAGCUGCU 20 3782 BCL11A-3298 − GUUCUUCACACACCCCCAUU 20 3783 BCL11A-3299 − CGCAGCGGCACGGGAAGUGG 20 3784 BCL11A-3300 + GCGGGAGGCUCCAUAGCCAU 20 3785 BCL11A-3301 − GGUGCACCGGCGCAGCCACA 20 3786 BCL11A-3302 − CUCCACACCGCCCGGGGAGC 20 3787 BCL11A-3303 + AAAGCGCCCUUCUGCCAGGC 20 3788 BCL11A-3304 + ACUCGGGUGAUGGGUGGCCA 20 3789 BCL11A-3305 + CUGCCUGGAGGCCGCGUAGC 20 3790 BCL11A-3306 + GUCCAGCUCCCCGGGCGGUG 20 3791 BCL11A-3307 − GAGCUGGACGGAGGGAUCUC 20 3792 BCL11A-3308 − UCUAGCCCACCGCUGUCCCC 20 3793 BCL11A-3309 + AGUUGUACAUGUGUAGCUGC 20 3794 BCL11A-3310 + AUUCUGCACCUAGUCCUGAA 20 3795 BCL11A-3311 − CCACCACGAGAACAGCUCGC 20 3796 BCL11A-3312 + CUCCUAGAGAAAUCCAUGGC 20 3797 BCL11A-3313 − UUUAACCUGCUAAGAAUACC 20 3798 BCL11A-3314 + GGACUAAACAGGGGGGGAGU 20 3799 BCL11A-3315 − GGCCACCUGGCCGAGGCCGA 20 3800 BCL11A-3316 + GGCUUGCUACCUGGCUGGAA 20 3801 BCL11A-3317 + CAUUCUGCACCUAGUCCUGA 20 3802 BCL11A-3318 + UGCUGGCCUGGGUGCACGCG 20 3803 BCL11A-3319 + UGUGGCCCUCGGCCUCGGCC 20 3804 BCL11A-3320 − CCGCCCGGGGAGCUGGACGG 20 3805 BCL11A-3321 − UGGCCGAGGCCGAGGGCCAC 20 3806 BCL11A-3322 + UGGGCAUCGCGGCCGGGGGC 20 3807 BCL11A-3323 + UCUCCUAGAGAAAUCCAUGG 20 3808 BCL11A-3324 + GGGCCAUCUCUUCCGCCCCC 20 3809 BCL11A-3325 + GUUGCAGUAACCUUUGCAUA 20 3810 BCL11A-3326 + AAAGGCACUCGGGUGAUGGG 20 3811 BCL11A-3327 + GAAGGGAUCUUUGAGCUGCC 20 3812 BCL11A-3328 + GCCACACAUCUUGAGCUCUC 20 3813 BCL11A-3329 − GGAGGGAUCUCGGGGCGCAG 20 3814 BCL11A-3330 − CCCGGAGAACGGGGACGAGG 20 3815 BCL11A-3331 + UGCAUAGGGCUGGGCCGGCC 20 3816 BCL11A-3332 − CGGGGCGCGGUCGUGGGCGU 20 3817 BCL11A-3333 + GAGGGGGGGCGUCGCCAGGA 20 3818 BCL11A-3334 − ACCGCCAGCUCCCCGGAACC 20 3819 BCL11A-3335 + GGUAUUCUUAGCAGGUUAAA 20 3820 BCL11A-3336 − AGGCUUCCGGCCUGGCAGAA 20 3821 BCL11A-3337 + GAUCCCUCCGUCCAGCUCCC 20 3822 BCL11A-3338 + UGGUAUUCUUAGCAGGUUAA 20 3823 BCL11A-3339 − AUCUACUUAGAAAGCGAACA 20 3824 BCL11A-3340 − CGGCCACCUGGCCGAGGCCG 20 3825 BCL11A-3341 − CAACACGCACAGAACACUCA 20 3826 BCL11A-3342 + GCCGGCCUGGGGACAGCGGU 20 3827 BCL11A-3343 − GCCACCACGAGAACAGCUCG 20 3828 BCL11A-3344 + GUAUUCUUAGCAGGUUAAAG 20 3829 BCL11A-3345 − CUCUAGGAGACUUAGAGAGC 20 3830 BCL11A-3346 − AACAGCCAUUCACCAGUGCA 20 3831 BCL11A-3347 + UUGCAAGAGAAACCAUGCAC 20 3832 BCL11A-3348 + GACUUGACCGGGGGCUGGGA 20 3833 BCL11A-3349 + ACCUUUGCAUAGGGCUGGGC 20 3834 BCL11A-3350 + UCUUUUGAGCUGGGCCUGCC 20 3835 BCL11A-3351 − GAGGCCUUCCACCAGGUCCU 20 3836 BCL11A-3352 + CUUUUGAGCUGGGCCUGCCC 20 3837 BCL11A-3353 + GGGAUCUUUGAGCUGCCUGG 20 3838 BCL11A-3354 − GGGCAGGCCCAGCUCAAAAG 20 3839 BCL11A-3355 + AGCACCCUGUCAAAGGCACU 20 3840 BCL11A-3356 + UGGACUAAACAGGGGGGGAG 20 3841 BCL11A-3357 + GCUCUUGAACUUGGCCACCA 20 3842 BCL11A-3358 + GAAUCCCAUGGAGAGGUGGC 20 3843 BCL11A-3359 − GUGCACCGGCGCAGCCACAC 20 3844 BCL11A-3360 − AAAGAUCCCUUCCUUAGCUU 20 3845 BCL11A-3361 + UGUCUGCAAUAUGAAUCCCA 20 3846 BCL11A-3362 − GGCAGGCCCAGCUCAAAAGA 20 3847 BCL11A-3363 + CCUCCGUCCAGCUCCCCGGG 20 3848 BCL11A-3364 − CUGUCCAAAAAGCUGCUGCU 20 3849 BCL11A-3365 + GCUUGAUGCGCUUAGAGAAG 20 3850 BCL11A-3366 − CGGCUUCGGGCUGAGCCUGG 20 3851 BCL11A-3367 + CACCAUGCCCUGCAUGACGU 20 3852 BCL11A-3368 − UCAAGAUGUGUGGCAGUUUU 20 3853 BCL11A-3369 − GUUCAAAUUUCAGAGCAACC 20 3854 BCL11A-3370 + GAGAAGGGGCUCAGCGAGCU 20 3855 BCL11A-3371 − GCAGCGGCACGGGAAGUGGA 20 3856 BCL11A-3372 + AAGUCUCCUAGAGAAAUCCA 20 3857 BCL11A-3373 + GGUGCCGGGUUCCGGGGAGC 20 3858 BCL11A-3374 − CCUGUCCAAAAAGCUGCUGC 20 3859 BCL11A-3375 + AUAUGAAUCCCAUGGAGAGG 20 3860 BCL11A-3376 − GGGCGCAGCGGCACGGGAAG 20 3861 BCL11A-3377 − GGCCGAGGCCGAGGGCCACA 20 3862 BCL11A-3378 + GCAAGUGUCCCUGUGGCCCU 20 3863 BCL11A-3379 + GGACUUGACCGGGGGCUGGG 20 3864 BCL11A-3380 + GCUUCUCGCCCAGGACCUGG 20 3865 BCL11A-3381 − GCGCCUGGGGGCGGAAGAGA 20 3866 BCL11A-3382 + GUCCCUGUGGCCCUCGGCCU 20 3867 BCL11A-3383 + AUCCCUCCGUCCAGCUCCCC 20 3868 BCL11A-3384 − GUGCCUUUGACAGGGUGCUG 20 3869 BCL11A-3385 − CCCAGAGAGCUCAAGAUGUG 20 3870 BCL11A-3386 + GGCCCUCGGCCUCGGCCAGG 20 3871 BCL11A-3387 − GAGAGCGAGAGGGUGGACUA 20 3872 BCL11A-3388 + GGGGGCGUCGCCAGGAAGGG 20 3873 BCL11A-3389 + AGAGAAGGGGCUCAGCGAGC 20 3874 BCL11A-3390 + CCACACAUCUUGAGCUCUCU 20 3875 BCL11A-3391 + GCUGCCCAGCAGCAGCUUUU 20 3876 BCL11A-3392 − GGAGCUGGACGGAGGGAUCU 20 3877 BCL11A-3393 − GGGGGCGGAAGAGAUGGCCC 20 3878 BCL11A-3394 − AGGAGACUUAGAGAGCUGGC 20 3879 BCL11A-3395 − GAGGCUUCCGGCCUGGCAGA 20 3880 BCL11A-3396 + AAUCCCAUGGAGAGGUGGCU 20 3881 BCL11A-3397 + UGUGCAUGUGCGUCUUCAUG 20 3882 BCL11A-3398 + CUCGCCCAGGACCUGGUGGA 20 3883 BCL11A-3399 + UCCUCCUCGUCCCCGUUCUC 20 3884 BCL11A-3400 + AGAAACCAUGCACUGGUGAA 20 3885 BCL11A-3401 − CUUCGGGCUGAGCCUGGAGG 20 3886 BCL11A-3402 + GCCGGGUUCCGGGGAGCUGG 20 3887 BCL11A-3403 + AGAAGGGGCUCAGCGAGCUG 20 3888 BCL11A-3404 + CUAAACAGGGGGGGAGUGGG 20 3889 BCL11A-3405 − CAAAUUUCAGAGCAACCUGG 20 3890 BCL11A-3406 + GAGGGAGGGGGGGCGUCGCC 20 3891 BCL11A-3407 + CCUCCUCGUCCCCGUUCUCC 20 3892 BCL11A-3408 + CCAGCAGCAGCUUUUUGGAC 20 3893 BCL11A-3409 − GCCCACCGCUGUCCCCAGGC 20 3894 BCL11A-3410 − GGAGACUUAGAGAGCUGGCA 20 3895 BCL11A-3411 − AGGAGCUGACGGAGAGCGAG 20 3896 BCL11A-3412 + GAGGGGCGGAUUGCAGAGGA 20 3897 BCL11A-3413 + CAUAGGGCUGGGCCGGCCUG 20 3898 BCL11A-3414 + GGCGGAUUGCAGAGGAGGGA 20 3899 BCL11A-3415 + GGAGGGGCGGAUUGCAGAGG 20 3900 BCL11A-3416 − UUACUGCAACCAUUCCAGCC 20 3901 BCL11A-3417 + GCAUAGGGCUGGGCCGGCCU 20 3902 BCL11A-3418 + GGGCGGAUUGCAGAGGAGGG 20 3903 BCL11A-3419 + GGGUUCCGGGGAGCUGGCGG 20 3904 BCL11A-3420 + UCUCGCCCGUGUGGCUGCGC 20 3905 BCL11A-3421 − CUUCCCAGCCACCUCUCCAU 20 3906 BCL11A-3422 − GCUGACGGAGAGCGAGAGGG 20 3907 BCL11A-3423 + GCGGAUUGCAGAGGAGGGAG 20 3908 BCL11A-3424 − GGAGCUGACGGAGAGCGAGA 20 3909 BCL11A-3425 − UCUCUCCACCGCCAGCUCCC 20 3910 BCL11A-3426 + UUGACCGGGGGCUGGGAGGG 20 3911 BCL11A-3427 + CGGAUUGCAGAGGAGGGAGG 20 3912 BCL11A-3428 − GCGGGGCGCGGUCGUGGGCG 20 3913 BCL11A-3429 + GAGCUGGGCCUGCCCGGGCC 20 3914 BCL11A-3430 + CUGGGCCGGCCUGGGGACAG 20 3915 BCL11A-3431 + UGUAGGGCUUCUCGCCCGUG 20 3916 BCL11A-3432 + CCAUGGAGAGGUGGCUGGGA 20 3917 BCL11A-3433 + GGAGGAGGGGCGGAUUGCAG 20 3918 BCL11A-3434 − CCUUCCCAGCCACCUCUCCA 20 3919 BCL11A-3435 + CCCGCGAGCUGUUCUCGUGG 20 3920 BCL11A-3436 + GAUUGCAGAGGAGGGAGGGG 20 3921 BCL11A-3437 + GGCCGGCCUGGGGACAGCGG 20 3922 BCL11A-3438 + GGAUUGCAGAGGAGGGAGGG 20 3923 BCL11A-3439 + ACCGGGGGCUGGGAGGGAGG 20 3924 BCL11A-3440 + CCGGGGGCUGGGAGGGAGGA 20 3925 BCL11A-3441 − GAACGGGGACGAGGAGGAAG 20 3926 BCL11A-3442 − CCCUCCUCCCUCCCAGCCCC 20 3927 BCL11A-3443 + CGGGGGCUGGGAGGGAGGAG 20 3928 BCL11A-3444 + GGCGCUUCAGCUUGCUGGCC 20 3929 BCL11A-3445 − CGGGGACGAGGAGGAAGAGG 20 3930 BCL11A-3446 − AGAGGAGGAGGAGGAGCUGA 20 3931 BCL11A-3447 + GGGCUGGGAGGGAGGAGGGG 20 3932 BCL11A-3448 − AGAGGAGGACGACGAGGAAG 20 3933 BCL11A-3449 − CGACGAGGAAGAGGAAGAAG 20 3934 BCL11A-3450 − GGAGGAAGAGGAGGACGACG 20 3935 BCL11A-3451 − CGAGGAAGAGGAAGAAGAGG 20 3936 BCL11A-3452 − GGAAGAAGAGGAGGAAGAGG 20 3937 BCL11A-3453 − AGAGGAAGAAGAGGAGGAAG 20 3938 BCL11A-3454 − AGAAGAGGAGGAAGAGGAGG 20 3939 BCL11A-3455 − AGAGGAGGAAGAGGAGGAGG 20 3940

Table 5A provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to first tier parameters. The targeting domains bind within first 500 bp of coding sequence downstream of start codon, good orthogonality, start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 5A Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO BCL11A-3456 − GAACCAGACCACGGCCCGUU 20 3941 BCL11A-3457 + GACCUGGAUGCCAACCUCCA 20 3942 BCL11A-3458 + GAUUAGAGCUCCAUGUG 17 3943 BCL11A-3459 − GAUUGUUUAUCAACGUCAUC 20 3944 BCL11A-3460 + GCACUCAUCCCAGGCGU 17 3945 BCL11A-3461 + GGGGAUUAGAGCUCCAUGUG 20 3946 BCL11A-3462 − GUGCAGAAUAUGCCCCG 17 3947

Table 5B provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to second tier parameters. The targeting domains bind within first 500 bp of coding sequence downstream of start codon, good orthogonality, and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL43A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL3A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 5B 2nd Tier Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO BCL11A-3463 − AACCAGACCACGGCCCG 17 3948 BCL11A-3464 + AAUUCCCGUUUGCUUAAGUG 20 3949 BCL11A-3465 − ACCAGACCACGGCCCGU 17 3950 BCL11A-3466 − AUGAACCAGACCACGGCCCG 20 3951 BCL11A-3467 + AUUCCCGUUUGCUUAAGUGC 20 3952 BCL11A-3468 − CCAGACCACGGCCCGUU 17 3953 BCL11A-3469 + CCCGUUUGCUUAAGUGC 17 3954 BCL11A-3470 + CCUGGAUGCCAACCUCC 17 3955 BCL11A-3471 + CUGGAUGCCAACCUCCA 17 3956 BCL11A-3472 + UCAUCCUCUGGCGUGAC 17 3957 BCL11A-3473 + UCCCGUUUGCUUAAGUG 17 3958 BCL11A-3474 + UCGUCAUCCUCUGGCGUGAC 20 3959 BCL11A-3475 + UCUGCACUCAUCCCAGGCGU 20 3960 BCL11A-3476 + UCUGGUUCAUCAUCUGU 17 3961 BCL11A-3477 − UGAACCAGACCACGGCCCGU 20 3962 BCL11A-3478 + UGACCUGGAUGCCAACCUCC 20 3963 BCL11A-3479 − UGAGUGCAGAAUAUGCCCCG 20 3964 BCL11A-3480 + UGCACUCAUCCCAGGCG 17 3965 BCL11A-3481 + UGGUCUGGUUCAUCAUCUGU 20 3966 BCL11A-3482 − UGUUUAUCAACGUCAUC 17 3967 BCL11A-3483 − UGUUUAUCAACGUCAUCUAG 20 3968 BCL11A-3484 − UUAUCAACGUCAUCUAG 17 3969 BCL11A-3485 + UUCUGCACUCAUCCCAGGCG 20 3970 BCL11A-3486 − UUGUUUAUCAACGUCAUCUA 20 3971 BCL11A-3487 − UUUAUCAACGUCAUCUA 17 3972

Table 5C provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to third tier parameters. The targeting domains bind within first 500 bp of coding sequence downstream of start codon and start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 5C 3rd Tier Target SEQ gRNA DNA Targeting Site  ID Name Strand Domain Length NO BCL11A-3488 − GAAAAAAGCAUCCAAUCCCG 20 3973 BCL11A-3489 + GAGAGGCCCCUCCAGUG 17 3974 BCL11A-3490 + GAGCUCCAUGUGCAGAACGA 20 3975 BCL11A-3491 − GAGGAAUUUGCCCCAAA 17 3976 BCL11A-3492 + GAGGAGAGGCCCCUCCAGUG 20 3977 BCL11A-3493 + GAGGAGGUCAUGAUCCCCUU 20 3978 BCL11A-3494 + GAGGUCAUGAUCCCCUU 17 3979 BCL11A-3495 − GCAUCCAGGUCACGCCA 17 3980 BCL11A-3496 − GCCACCUUCCCCUUCACCAA 20 3981 BCL11A-3497 − GCCAGAUGAACUUCCCA 17 3982 BCL11A-3498 − GCCAGAUGAACUUCCCAUUG 20 3983 BCL11A-3499 − GCCCGUUGGGAGCUCCAGAA 20 3984 BCL11A-3500 − GCCUCUGCUUAGAAAAAGCU 20 3985 BCL11A-3501 + GCUCCAUGUGCAGAACG 17 3986 BCL11A-3502 − GCUCUAAUCCCCACGCC 17 3987 BCL11A-3503 − GGACAUUCUUAUUUUUA 17 3988 BCL11A-3504 − GGAGCUCUAAUCCCCACGCC 20 3989 BCL11A-3505 − GGAUCAUGACCUCCUCACCU 20 3990 BCL11A-3506 + GGAUGCCAACCUCCACGGGA 20 3991 BCL11A-3507 + GGCACUGCCCACAGGUG 17 3992 BCL11A-3508 − GGCCCGUUGGGAGCUCCAGA 20 3993 BCL11A-3509 − GGGGGACAUUCUUAUUUUUA 20 3994 BCL11A-3510 − GGUUGGCAUCCAGGUCACGC 20 3995 BCL11A-3511 + GGUUUGCCUUGCUUGCG 17 3996 BCL11A-3512 + GUGCAGAACGAGGGGAG 17 3997 BCL11A-3513 − GUGCCAGAUGAACUUCCCAU 20 3998

Table 5D provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to forth tier parameters. The targeting domains bind within first 500 bp of coding sequence downstream of start codon and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL4A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 5D Target SEQ 4th Tier DNA Targeting Site ID gRNA Name Strand Domain Length NO BCL11A-3514 − AAAAAGCAUCCAAUCCC 17 3999 BCL11A-3515 + AAAAAUAAGAAUGUCCCCCA 20 4000 BCL11A-3516 − AAAAGCAUCCAAUCCCG 17 4001 BCL11A-3517 + AAAAUAAGAAUGUCCCCCAA 20 4002 BCL11A-3518 − AAACCCCAGCACUUAAGCAA 20 4003 BCL11A-3519 + AAAUAAGAAUGUCCCCCAAU 20 4004 BCL11A-3520 − AACCCCAGCACUUAAGCAAA 20 4005 BCL11A-3521 + AAUAAGAAUGUCCCCCA 17 4006 BCL11A-3522 − ACCCCAGCACUUAAGCAAAC 20 4007 BCL11A-3523 − ACCUUCCCCUUCACCAA 17 4008 BCL11A-3524 + AGAGCUCCAUGUGCAGA 17 4009 BCL11A-3525 + AGAGCUCCAUGUGCAGAACG 20 4010 BCL11A-3526 − AGAUGAACUUCCCAUUG 17 4011 BCL11A-3527 − AGCCAUUCUUACAGAUG 17 4012 BCL11A-3528 + AGCUCCAUGUGCAGAAC 17 4013 BCL11A-3529 + AGCUCCAUGUGCAGAACGAG 20 4014 BCL11A-3530 − AGCUCUAAUCCCCACGC 17 4015 BCL11A-3531 − AGGAAUUUGCCCCAAAC 17 4016 BCL11A-3532 + AGGAGGUCAUGAUCCCCUUC 20 4017 BCL11A-3533 + AGGUCAUGAUCCCCUUC 17 4018 BCL11A-3534 − AGUGCCAGAUGAACUUCCCA 20 4019 BCL11A-3535 + AUAAGAAUGUCCCCCAA 17 4020 BCL11A-3536 + AUCCCAGGCGUGGGGAU 17 4021 BCL11A-3537 + AUCCCCUUCUGGAGCUCCCA 20 4022 BCL11A-3538 + AUCUGGCACUGCCCACAGGU 20 4023 BCL11A-3539 − AUGCAAUGGCAGCCUCUGCU 20 4024 BCL11A-3540 + AUGUGCAGAACGAGGGG 17 4025 BCL11A-3541 + AUUAGAGCUCCAUGUGCAGA 20 4026 BCL11A-3542 + AUUCUGCACUCAUCCCAGGC 20 4027 BCL11A-3543 − AUUUUUAUCGAGCACAA 17 4028 BCL11A-3544 − CAAUGGCAGCCUCUGCU 17 4029 BCL11A-3545 − CACGCCUGGGAUGAGUG 17 4030 BCL11A-3546 − CAGAUGAACUUCCCAUU 17 4031 BCL11A-3547 + CAUCUCGAUUGGUGAAG 17 4032 BCL11A-3548 + CAUGUGCAGAACGAGGG 17 4033 BCL11A-3549 + CAUGUGCAGAACGAGGGGAG 20 4034 BCL11A-3550 + CCACAGCUUUUUCUAAG 17 4035 BCL11A-3551 − CCACGGCCCGUUGGGAGCUC 20 4036 BCL11A-3552 − CCAGAUGAACUUCCCAU 17 4037 BCL11A-3553 − CCAGCACUUAAGCAAAC 17 4038 BCL11A-3554 − CCCAGCACUUAAGCAAA 17 4039 BCL11A-3555 − CCCCACGCCUGGGAUGAGUG 20 4040 BCL11A-3556 − CCCCAGCACUUAAGCAA 17 4041 BCL11A-3557 − CCCCUUCACCAAUCGAG 17 4042 BCL11A-3558 − CCCGUUGGGAGCUCCAG 17 4043 BCL11A-3559 + CCCUUCUGGAGCUCCCA 17 4044 BCL11A-3560 − CCGUUGGGAGCUCCAGA 17 4045 BCL11A-3561 − CCUGUGGGCAGUGCCAG 17 4046 BCL11A-3562 − CGGCCCGUUGGGAGCUC 17 4047 BCL11A-3563 − CGGCCCGUUGGGAGCUCCAG 20 4048 BCL11A-3564 − CGUUGGGAGCUCCAGAA 17 4049 BCL11A-3565 + CGUUUGUGCUCGAUAAAAAU 20 4050 BCL11A-3566 − CUAGAGGAAUUUGCCCCAAA 20 4051 BCL11A-3567 + CUCAUCCCAGGCGUGGGGAU 20 4052 BCL11A-3568 + CUCCAUGUGCAGAACGA 17 4053 BCL11A-3569 + CUCCAUGUGCAGAACGAGGG 20 4054 BCL11A-3570 − CUCCCCUCGUUCUGCAC 17 4055 BCL11A-3571 − CUCCUCCCCUCGUUCUGCAC 20 4056 BCL11A-3572 − CUCUAAUCCCCACGCCUGGG 20 4057 BCL11A-3573 + CUGCACUCAUCCCAGGC 17 4058 BCL11A-3574 − CUUAUUUUUAUCGAGCACAA 20 4059 BCL11A-3575 − CUUCCCCUUCACCAAUCGAG 20 4060 BCL11A-3576 + UAAGAAUGUCCCCCAAU 17 4061 BCL11A-3577 − UAAUCCCCACGCCUGGG 17 4062 BCL11A-3578 + UAGAGCUCCAUGUGCAGAAC 20 4063 BCL11A-3579 − UAGAGGAAUUUGCCCCAAAC 20 4064 BCL11A-3580 + UAUCCACAGCUUUUUCUAAG 20 4065 BCL11A-3581 − UCACCUGUGGGCAGUGCCAG 20 4066 BCL11A-3582 + UCAUCUCGAUUGGUGAA 17 4067 BCL11A-3583 + UCAUCUGGCACUGCCCACAG 20 4068 BCL11A-3584 + UCAUCUGUAAGAAUGGCUUC 20 4069 BCL11A-3585 − UCAUGACCUCCUCACCU 17 4070 BCL11A-3586 + UCCAUGUGCAGAACGAG 17 4071 BCL11A-3587 + UCCAUGUGCAGAACGAGGGG 20 4072 BCL11A-3588 − UCCCCUCGUUCUGCACA 17 4073 BCL11A-3589 − UCCUCCCCUCGUUCUGCACA 20 4074 BCL11A-3590 − UCUGCUUAGAAAAAGCU 17 4075 BCL11A-3591 + UCUGGCACUGCCCACAG 17 4076 BCL11A-3592 + UCUGGCACUGCCCACAGGUG 20 4077 BCL11A-3593 + UCUGUAAGAAUGGCUUC 17 4078 BCL11A-3594 − UGAAAAAAGCAUCCAAUCCC 20 4079 BCL11A-3595 − UGAAGCCAUUCUUACAGAUG 20 4080 BCL11A-3596 + UGCCAACCUCCACGGGA 17 4081 BCL11A-3597 − UGCCAGAUGAACUUCCCAUU 20 4082 BCL11A-3598 + UGCUUUUUUCAUCUCGAUUG 20 4083 BCL11A-3599 − UGGAGCUCUAAUCCCCACGC 20 4084 BCL11A-3600 + UGGCACUGCCCACAGGU 17 4085 BCL11A-3601 − UGGCAUCCAGGUCACGC 17 4086 BCL11A-3602 + UGGGGUUUGCCUUGCUUGCG 20 4087 BCL11A-3603 − UUAUUUUUAUCGAGCACAAA 20 4088 BCL11A-3604 + UUCAUCUCGAUUGGUGA 17 4089 BCL11A-3605 − UUGGCAUCCAGGUCACGCCA 20 4090 BCL11A-3606 + UUGUGCUCGAUAAAAAU 17 4091 BCL11A-3607 + UUUCAUCUCGAUUGGUG 17 4092 BCL11A-3608 + UUUCAUCUCGAUUGGUGAAG 20 4093 BCL11A-3609 + UUUUCAUCUCGAUUGGUGAA 20 4094 BCL11A-3610 − UUUUUAUCGAGCACAAA 17 4095 BCL11A-3611 + UUUUUCAUCUCGAUUGGUGA 20 4096 BCL11A-3612 + UUUUUUCAUCUCGAUUG 17 4097 BCL11A-3613 + UUUUUUCAUCUCGAUUGGUG 20 4098

Table 5E provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to fifth tier parameters. The targeting domains target outside the first 500 bp of coding sequence downstream of start codon. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 5E Target SEQ 5th Tier DNA Targeting Site ID gRNA Name Strand Domain Length NO BCL11A-3614 + UCGUCGGACUUGACCGUCAU 20 4099 BCL11A-3615 + GUCGUCGGACUUGACCGUCA 20 4100 BCL11A-3616 + CGUCGUCGGACUUGACCGUC 20 4101 BCL11A-3617 + CGUCGGACUUGACCGUCAUG 20 4102 BCL11A-3618 − CCCAUAUUAGUGGUCCGGGC 20 4103 BCL11A-3619 + GCGGUCCGACUCGCCGGCCA 20 4104 BCL11A-3620 + CUCCGAGGAGUGCUCCGACG 20 4105 BCL11A-3621 − CCCCCAUUCGGCGUAGUACC 20 4106 BCL11A-3622 + UCUCCGAGGAGUGCUCCGAC 20 4107 BCL11A-3623 − CCCGCGGGUUGGUAUCCCUU 20 4108 BCL11A-3624 + GCGAGUACACGUUCUCCGUG 20 4109 BCL11A-3625 − CCCAUUCGGCGUAGUACCCA 20 4110 BCL11A-3626 + CUCCGUGUUGGGCAUCGCGG 20 4111 BCL11A-3627 + CCGCGCUUAUGCUUCUCGCC 20 4112 BCL11A-3628 − CGACGAAGACUCGGUGGCCG 20 4113 BCL11A-3629 − ACCCCCACCGCAUAGAGCGC 20 4114 BCL11A-3630 + ACUACGCCGAAUGGGGGUGU 20 4115 BCL11A-3631 + CCGGGCCCGGACCACUAAUA 20 4116 BCL11A-3632 + CGCGUAGCCGGCGAGCCACU 20 4117 BCL11A-3633 − UCGGAGCACUCCUCGGAGAA 20 4118 BCL11A-3634 − CGGAGCACUCCUCGGAGAAC 20 4119 BCL11A-3635 + UCUCUGGGUACUACGCCGAA 20 4120 BCL11A-3636 + UGCCGCAGAACUCGCAUGAC 20 4121 BCL11A-3637 + GAUACCAACCCGCGGGGUCA 20 4122 BCL11A-3638 + GGAUACCAACCCGCGGGGUC 20 4123 BCL11A-3639 + GGGAUACCAACCCGCGGGGU 20 4124 BCL11A-3640 − CCCCCACCGCAUAGAGCGCC 20 4125 BCL11A-3641 + GGUUGGGGUCGUUCUCGCUC 20 4126 BCL11A-3642 − GCACGCCCCAUAUUAGUGGU 20 4127 BCL11A-3643 − UAAGCGCAUCAAGCUCGAGA 20 4128 BCL11A-3644 + GUUCUCCGAGGAGUGCUCCG 20 4129 BCL11A-3645 + UCUCGAGCUUGAUGCGCUUA 20 4130 BCL11A-3646 − CUAAGCGCAUCAAGCUCGAG 20 4131 BCL11A-3647 − GUCGGAGCACUCCUCGGAGA 20 4132 BCL11A-3648 − UGGCCGCGGCUGCUCCCCGG 20 4133 BCL11A-3649 − CCCCACCGCAUAGAGCGCCU 20 4134 BCL11A-3650 + CCUGAAGGGAUACCAACCCG 20 4135 BCL11A-3651 − GCGCUUCUCCACACCGCCCG 20 4136 BCL11A-3652 − GCGCCCUGCCCGACGUCAUG 20 4137 BCL11A-3653 − AACCCGGCACCAGCGACUUG 20 4138 BCL11A-3654 + CUCUGGGUACUACGCCGAAU 20 4139 BCL11A-3655 + CCCGUUCUCCGGGAUCAGGU 20 4140 BCL11A-3656 − GAACGACCCCAACCUGAUCC 20 4141 BCL11A-3657 + ACGCCGAAUGGGGGUGUGUG 20 4142 BCL11A-3658 + GUCGCUGGUGCCGGGUUCCG 20 4143 BCL11A-3659 − CCCCGGGCGAGUCGGCCUCG 20 4144 BCL11A-3660 + CGGUGCACCACCAGGUUGCU 20 4145 BCL11A-3661 − GUCCACCACCGAGACAUCAC 20 4146 BCL11A-3662 − UUAAUGGCCGCGGCUGCUCC 20 4147 BCL11A-3663 + CUCUCUGGGUACUACGCCGA 20 4148 BCL11A-3664 + GCGCAAACUCCCGUUCUCCG 20 4149 BCL11A-3665 + CCCGGGCCCGGACCACUAAU 20 4150 BCL11A-3666 + GCCCCCAGGCGCUCUAUGCG 20 4151 BCL11A-3667 − AUCGCCUUUUGCCUCCUCGU 20 4152 BCL11A-3668 − CCUCGUCGGAGCACUCCUCG 20 4153 BCL11A-3669 + GAGCUUGAUGCGCUUAGAGA 20 4154 BCL11A-3670 + CCCCGUUCUCCGGGAUCAGG 20 4155 BCL11A-3671 − CGGCCGCGAUGCCCAACACG 20 4156 BCL11A-3672 + GCCCCCCGAGGCCGACUCGC 20 4157 BCL11A-3673 − CCCGGCCGCGAUGCCCAACA 20 4158 BCL11A-3674 − CUCCUCGUCGGAGCACUCCU 20 4159 BCL11A-3675 + GUCUCGGUGGUGGACUAAAC 20 4160 BCL11A-3676 + CCCCAGGCGCUCUAUGCGGU 20 4161 BCL11A-3677 + GGUCGCACAGGUUGCACUUG 20 4162 BCL11A-3678 + AGUCGCUGGUGCCGGGUUCC 20 4163 BCL11A-3679 − CCCGGUCAAGUCCAAGUCAU 20 4164 BCL11A-3680 − AGAACGACCCCAACCUGAUC 20 4165 BCL11A-3681 + UCCGUGUUGGGCAUCGCGGC 20 4166 BCL11A-3682 − CCUCCUCGUCGGAGCACUCC 20 4167 BCL11A-3683 − UCACUUGGACCCCCACCGCA 20 4168 BCL11A-3684 − CCCAACCUGAUCCCGGAGAA 20 4169 BCL11A-3685 − ACUACGGCUUCGGGCUGAGC 20 4170 BCL11A-3686 − UUUGCGCUUCUCCACACCGC 20 4171 BCL11A-3687 + AAGUCGCUGGUGCCGGGUUC 20 4172 BCL11A-3688 − CCCCAACCUGAUCCCGGAGA 20 4173 BCL11A-3689 − AAGACUCGGUGGCCGGCGAG 20 4174 BCL11A-3690 − GCGCGGCCACCUGGCCGAGG 20 4175 BCL11A-3691 − AAUCGCCUUUUGCCUCCUCG 20 4176 BCL11A-3692 − ACGACCCCAACCUGAUCCCG 20 4177 BCL11A-3693 − GAUCCCGGAGAACGGGGACG 20 4178 BCL11A-3694 + GGGGCAGGUCGAACUCCUUC 20 4179 BCL11A-3695 − UGGCUAUGGAGCCUCCCGCC 20 4180 BCL11A-3696 + CCCCCAGGCGCUCUAUGCGG 20 4181 BCL11A-3697 − GCGGUUGAAUCCAAUGGCUA 20 4182 BCL11A-3698 − CUACGGCUUCGGGCUGAGCC 20 4183 BCL11A-3699 − ACAGCUCGCGGGGCGCGGUC 20 4184 BCL11A-3700 − CCCCCCUGUUUAGUCCACCA 20 4185 BCL11A-3701 + CGCAUGACUUGGACUUGACC 20 4186 BCL11A-3702 − CACGGAAGUCCCCUGACCCC 20 4187 BCL11A-3703 − CCUCCCGCCAUGGAUUUCUC 20 4188 BCL11A-3704 + UCUCGGUGGUGGACUAAACA 20 4189 BCL11A-3705 + UGAACUUGGCCACCACGGAC 20 4190 BCL11A-3706 − CUUCUCUAAGCGCAUCAAGC 20 4191 BCL11A-3707 + AGCGCAAACUCCCGUUCUCC 20 4192 BCL11A-3708 + UCGGUGGUGGACUAAACAGG 20 4193 BCL11A-3709 − CGCCACCACGAGAACAGCUC 20 4194 BCL11A-3710 − CUCCCGCCAUGGAUUUCUCU 20 4195 BCL11A-3711 + CGAGCUUGAUGCGCUUAGAG 20 4196 BCL11A-3712 + AUGCCCUGCAUGACGUCGGG 20 4197 BCL11A-3713 − UCUCUAAGCGCAUCAAGCUC 20 4198 BCL11A-3714 + GUCCAAGUGAUGUCUCGGUG 20 4199 BCL11A-3715 + CCCCCGAGGCCGACUCGCCC 20 4200 BCL11A-3716 + CCCCGAGGCCGACUCGCCCG 20 4201 BCL11A-3717 + GAAAUUUGAACGUCUUGCCG 20 4202 BCL11A-3718 + GUCGCUGCGUCUGCCCUCUU 20 4203 BCL11A-3719 − UGGAGGCGGCGCGCCACCAC 20 4204 BCL11A-3720 + CUUCUCGAGCUUGAUGCGCU 20 4205 BCL11A-3721 + GAAGCGCAAACUCCCGUUCU 20 4206 BCL11A-3722 − GAGAGAGGCUUCCGGCCUGG 20 4207 BCL11A-3723 − UCCCCGGGCGAGUCGGCCUC 20 4208 BCL11A-3724 + CAAGUCGCUGGUGCCGGGUU 20 4209 BCL11A-3725 − CAUAGAGCGCCUGGGGGCGG 20 4210 BCL11A-3726 + CUCGGUGGUGGACUAAACAG 20 4211 BCL11A-3727 + CCCCCCGAGGCCGACUCGCC 20 4212 BCL11A-3728 − GGUUUCUCUUGCAACACGCA 20 4213 BCL11A-3729 + ACUUGGACUUGACCGGGGGC 20 4214 BCL11A-3730 − UGAUCCCGGAGAACGGGGAC 20 4215 BCL11A-3731 + UGUCUGGAGUCUCCGAAGCU 20 4216 BCL11A-3732 − AUGGAUUUCUCUAGGAGACU 20 4217 BCL11A-3733 − UGCGGUUGAAUCCAAUGGCU 20 4218 BCL11A-3734 − CUCCCCGGGCGAGUCGGCCU 20 4219 BCL11A-3735 − CCUGAUCCCGGAGAACGGGG 20 4220 BCL11A-3736 + UGUCUCGGUGGUGGACUAAA 20 4221 BCL11A-3737 + CGGUGGUGGACUAAACAGGG 20 4222 BCL11A-3738 + UGCCCACCAAGUCGCUGGUG 20 4223 BCL11A-3739 − CGUGGUGGCCAAGUUCAAGA 20 4224 BCL11A-3740 − CAUCACCCGAGUGCCUUUGA 20 4225 BCL11A-3741 − GCGGCAAGACGUUCAAAUUU 20 4226 BCL11A-3742 + AAGGGCUCUCGAGCUUCCAU 20 4227 BCL11A-3743 + GUCUGGAGUCUCCGAAGCUA 20 4228 BCL11A-3744 − CCCCGGCCGCGAUGCCCAAC 20 4229 BCL11A-3745 + CUGUCAAAGGCACUCGGGUG 20 4230 BCL11A-3746 + CUUGGACUUGACCGGGGGCU 20 4231 BCL11A-3747 + GACUUGGACUUGACCGGGGG 20 4232 BCL11A-3748 + UGCGUCUGCCCUCUUUUGAG 20 4233 BCL11A-3749 + GGAGGCAAAAGGCGAUUGUC 20 4234 BCL11A-3750 − GCAACACGCACAGAACACUC 20 4235 BCL11A-3751 + GCAGUAACCUUUGCAUAGGG 20 4236 BCL11A-3752 − UGGUGCACCGGCGCAGCCAC 20 4237 BCL11A-3753 − UGGUGGCCAAGUUCAAGAGC 20 4238 BCL11A-3754 − GCAUAAGCGCGGCCACCUGG 20 4239 BCL11A-3755 + UUGCAUAGGGCUGGGCCGGC 20 4240 BCL11A-3756 − CCAACCUGAUCCCGGAGAAC 20 4241 BCL11A-3757 − AGAUGUGUGGCAGUUUUCGG 20 4242 BCL11A-3758 − CAGUUUUCGGAUGGAAGCUC 20 4243 BCL11A-3759 − GCUCCCCGGGCGAGUCGGCC 20 4244 BCL11A-3760 − GGGUGGACUACGGCUUCGGG 20 4245 BCL11A-3761 − UAUCCCUUCAGGACUAGGUG 20 4246 BCL11A-3762 − AUCUCGGGGCGCAGCGGCAC 20 4247 BCL11A-3763 + CGCUCUUGAACUUGGCCACC 20 4248 BCL11A-3764 − GCACCGGCGCAGCCACACGG 20 4249 BCL11A-3765 + GCUUCUCGCCCAGGACCUGG 20 4250 BCL11A-3766 − UCCCGGAGAACGGGGACGAG 20 4251 BCL11A-3767 + CAGCACCCUGUCAAAGGCAC 20 4252 BCL11A-3768 + CAUUCUGCACCUAGUCCUGA 20 4253 BCL11A-3769 − CUUUAACCUGCUAAGAAUAC 20 4254 BCL11A-3770 − GUCUCUCCACCGCCAGCUCC 20 4255 BCL11A-3771 − UCUCUCCACCGCCAGCUCCC 20 4256 BCL11A-3772 + UGCUUCUCGCCCAGGACCUG 20 4257 BCL11A-3773 + GCGCCGCCUCCAGGCUCAGC 20 4258 BCL11A-3774 + AGAUCCCUCCGUCCAGCUCC 20 4259 BCL11A-3775 − CGAGAGGGUGGACUACGGCU 20 4260 BCL11A-3776 + CGUCCAGCUCCCCGGGCGGU 20 4261 BCL11A-3777 + CCAGCUCUCUAAGUCUCCUA 20 4262 BCL11A-3778 + UCGCAUGACUUGGACUUGAC 20 4263 BCL11A-3779 + GCACCAUGCCCUGCAUGACG 20 4264 BCL11A-3780 + AAGGCGAUUGUCUGGAGUCU 20 4265 BCL11A-3781 + GCCUGGAGGCCGCGUAGCCG 20 4266 BCL11A-3782 − GCGGCCACCUGGCCGAGGCC 20 4267 BCL11A-3783 − AGAAUACCAGGAUCAGUAUC 20 4268 BCL11A-3784 − GAUGUGUGGCAGUUUUCGGA 20 4269 BCL11A-3785 − UCUCCACACCGCCCGGGGAG 20 4270 BCL11A-3786 − CCUGGAGGCGGCGCGCCACC 20 4271 BCL11A-3787 + CUGGUAUUCUUAGCAGGUUA 20 4272 BCL11A-3788 + UAGAGAAGGGGCUCAGCGAG 20 4273 BCL11A-3789 + GAGUGUUCUGUGCGUGUUGC 20 4274 BCL11A-3790 − AAUAACCCCUUUAACCUGCU 20 4275 BCL11A-3791 + AAAGCGCCCUUCUGCCAGGC 20 4276 BCL11A-3792 + GUCCAGCUCCCCGGGCGGUG 20 4277 BCL11A-3793 + AAGGGCGGCUUGCUACCUGG 20 4278 BCL11A-3794 + GAAAGCGCCCUUCUGCCAGG 20 4279 BCL11A-3795 + AGGGCGGCUUGCUACCUGGC 20 4280 BCL11A-3796 − CGCGGGGCGCGGUCGUGGGC 20 4281 BCL11A-3797 − GCGAGGCCUUCCACCAGGUC 20 4282 BCL11A-3798 + ACUUCCCGUGCCGCUGCGCC 20 4283 BCL11A-3799 − GCACAGAACACUCAUGGAUU 20 4284 BCL11A-3800 + CCAGCUCCCCGGGCGGUGUG 20 4285 BCL11A-3801 − ACCGCCCGGGGAGCUGGACG 20 4286 BCL11A-3802 + UGGUUGCAGUAACCUUUGCA 20 4287 BCL11A-3803 − AGGAGACUUAGAGAGCUGGC 20 4288 BCL11A-3804 − ACCGGCGCAGCCACACGGGC 20 4289 BCL11A-3805 + ACAUUCUGCACCUAGUCCUG 20 4290 BCL11A-3806 + GUGUUCUGUGCGUGUUGCAA 20 4291 BCL11A-3807 − UGGCCCUGGCCACCCAUCAC 20 4292 BCL11A-3808 + UGCAUAGGGCUGGGCCGGCC 20 4293 BCL11A-3809 − AAUACCAGGAUCAGUAUCGA 20 4294 BCL11A-3810 + UCCUGAAGGGAUACCAACCC 20 4295 BCL11A-3811 + CUCCUAGAGAAAUCCAUGGC 20 4296 BCL11A-3812 + UGGCGGUGGAGAGACCGUCG 20 4297 BCL11A-3813 − GGAUUUCUCUAGGAGACUUA 20 4298 BCL11A-3814 + CUCGCAUGACUUGGACUUGA 20 4299 BCL11A-3815 − GAUCUCGGGGCGCAGCGGCA 20 4300 BCL11A-3816 + GGUGGUGGACUAAACAGGGG 20 4301 BCL11A-3817 + AGGCCUCGCUGAAGUGCUGC 20 4302 BCL11A-3818 + CCACCAGGUUGCUCUGAAAU 20 4303 BCL11A-3819 − ACCGCAUAGAGCGCCUGGGG 20 4304 BCL11A-3820 − CCAGCAAGCUGAAGCGCCAC 20 4305 BCL11A-3821 + GGCCUCGCUGAAGUGCUGCA 20 4306 BCL11A-3822 − CGUGCACCCAGGCCAGCAAG 20 4307 BCL11A-3823 + GGCGGGAGGCUCCAUAGCCA 20 4308 BCL11A-3824 + AGGAGGCAAAAGGCGAUUGU 20 4309 BCL11A-3825 − AAAGAUCCCUUCCUUAGCUU 20 4310 BCL11A-3826 + GGAGUCUCCGAAGCUAAGGA 20 4311 BCL11A-3827 + GCGCUUAGAGAAGGGGCUCA 20 4312 BCL11A-3828 + CAGCUUUUUGGACAGGCCCC 20 4313 BCL11A-3829 + GCACUCGGGUGAUGGGUGGC 20 4314 BCL11A-3830 + CACGCCCACGACCGCGCCCC 20 4315 BCL11A-3831 + AAGUUGUACAUGUGUAGCUG 20 4316 BCL11A-3832 − AGUCCGUGGUGGCCAAGUUC 20 4317 BCL11A-3833 − CCCGGAGAACGGGGACGAGG 20 4318 BCL11A-3834 − CGGGCAGGCCCAGCUCAAAA 20 4319 BCL11A-3835 + UGGUAUUCUUAGCAGGUUAA 20 4320 BCL11A-3836 + UUGUCUGCAAUAUGAAUCCC 20 4321 BCL11A-3837 + GUCUCCUAGAGAAAUCCAUG 20 4322 BCL11A-3838 + UGGACUUGACCGGGGGCUGG 20 4323 BCL11A-3839 + UGGAGUCUCCGAAGCUAAGG 20 4324 BCL11A-3840 + UGAGCUGGGCCUGCCCGGGC 20 4325 BCL11A-3841 − CAAAGAUCCCUUCCUUAGCU 20 4326 BCL11A-3842 + UGCCACACAUCUUGAGCUCU 20 4327 BCL11A-3843 − CCGCCCGGGGAGCUGGACGG 20 4328 BCL11A-3844 + AGAGAAGGGGCUCAGCGAGC 20 4329 BCL11A-3845 − GGAGACUUAGAGAGCUGGCA 20 4330 BCL11A-3846 + GAAUCCCAUGGAGAGGUGGC 20 4331 BCL11A-3847 + CGCUGAAGUGCUGCAUGGAG 20 4332 BCL11A-3848 + AGGACAUUCUGCACCUAGUC 20 4333 BCL11A-3849 + AAUCCCAUGGAGAGGUGGCU 20 4334 BCL11A-3850 + UGAGCUCUCUGGGUACUACG 20 4335 BCL11A-3851 − GGGCCACAGGGACACUUGCG 20 4336 BCL11A-3852 − UAGGAGACUUAGAGAGCUGG 20 4337 BCL11A-3853 − CCUUUGACAGGGUGCUGCGG 20 4338 BCL11A-3854 − UGGCCGAGGCCGAGGGCCAC 20 4339 BCL11A-3855 + GGAAGGGAUCUUUGAGCUGC 20 4340 BCL11A-3856 + UCUAAGUAGAUUCUUAAUCC 20 4341 BCL11A-3857 − GGGGCGCAGCGGCACGGGAA 20 4342 BCL11A-3858 − CUGGCCGAGGCCGAGGGCCA 20 4343 BCL11A-3859 − CUCAAGAUGUGUGGCAGUUU 20 4344 BCL11A-3860 + CGAAGCUAAGGAAGGGAUCU 20 4345 BCL11A-3861 + UGCCAGCUCUCUAAGUCUCC 20 4346 BCL11A-3862 + UCUCCUAGAGAAAUCCAUGG 20 4347 BCL11A-3863 − GCCACCACGAGAACAGCUCG 20 4348 BCL11A-3864 + UCUGCAAUAUGAAUCCCAUG 20 4349 BCL11A-3865 − CAGCUCCAUGCAGCACUUCA 20 4350 BCL11A-3866 − GCCUGUCCAAAAAGCUGCUG 20 4351 BCL11A-3867 − UAAGAAUACCAGGAUCAGUA 20 4352 BCL11A-3868 − GGAUCUCGGGGCGCAGCGGC 20 4353 BCL11A-3869 − GGCAGUUUUCGGAUGGAAGC 20 4354 BCL11A-3870 − CGGUCGUGGGCGUGGGCGAC 20 4355 BCL11A-3871 + GCAUCGCGGCCGGGGGCAGG 20 4356 BCL11A-3872 − AAUCUACUUAGAAAGCGAAC 20 4357 BCL11A-3873 + AAGGGGUUAUUGUCUGCAAU 20 4358 BCL11A-3874 + GGACUUGACCGGGGGCUGGG 20 4359 BCL11A-3875 − UCAUGGAUUAAGAAUCUACU 20 4360 BCL11A-3876 − AGAGGCUUCCGGCCUGGCAG 20 4361 BCL11A-3877 − GGCCUUCCACCAGGUCCUGG 20 4362 BCL11A-3878 + UGGCGCUUCAGCUUGCUGGC 20 4363 BCL11A-3879 − CCGCAUAGAGCGCCUGGGGG 20 4364 BCL11A-3880 + GGACCUGGUGGAAGGCCUCG 20 4365 BCL11A-3881 − CCUUCCACCAGGUCCUGGGC 20 4366 BCL11A-3882 + UGUCUGCAAUAUGAAUCCCA 20 4367 BCL11A-3883 − GGAGCUGGACGGAGGGAUCU 20 4368 BCL11A-3884 + GACUUGACCGGGGGCUGGGA 20 4369 BCL11A-3885 − UCCUUCCCAGCCACCUCUCC 20 4370 BCL11A-3886 + CUCUUUUGAGCUGGGCCUGC 20 4371 BCL11A-3887 − UGCGCUUCUCCACACCGCCC 20 4372 BCL11A-3888 + GCAAGAGAAACCAUGCACUG 20 4373 BCL11A-3889 − GGGAGCUGGACGGAGGGAUC 20 4374 BCL11A-3890 + GUUCCGGGGAGCUGGCGGUG 20 4375 BCL11A-3891 + UGAAUCCCAUGGAGAGGUGG 20 4376 BCL11A-3892 + CGGGUUCCGGGGAGCUGGCG 20 4377 BCL11A-3893 + GUGGACUAAACAGGGGGGGA 20 4378 BCL11A-3894 + GGCUGCCCAGCAGCAGCUUU 20 4379 BCL11A-3895 + GAAGGGAUCUUUGAGCUGCC 20 4380 BCL11A-3896 − CCUUCCCAGCCACCUCUCCA 20 4381 BCL11A-3897 − GCGCAGCGGCACGGGAAGUG 20 4382 BCL11A-3898 + GGGUUCCGGGGAGCUGGCGG 20 4383 BCL11A-3899 + UCCUCCUCGUCCCCGUUCUC 20 4384 BCL11A-3900 − GCAGCGGCACGGGAAGUGGA 20 4385 BCL11A-3901 − UGCUGGGCAGCCCCAGCUCG 20 4386 BCL11A-3902 − GGGCGCAGCGGCACGGGAAG 20 4387 BCL11A-3903 − ACACCGCCCGGGGAGCUGGA 20 4388 BCL11A-3904 + CCCAUGGAGAGGUGGCUGGG 20 4389 BCL11A-3905 + UUCCUCCUCGUCCCCGUUCU 20 4390 BCL11A-3906 − AUCUACUUAGAAAGCGAACA 20 4391 BCL11A-3907 − CCCGGGCAGGCCCAGCUCAA 20 4392 BCL11A-3908 − CACACCGCCCGGGGAGCUGG 20 4393 BCL11A-3909 + ACUAAACAGGGGGGGAGUGG 20 4394 BCL11A-3910 + GACCGGGGGCUGGGAGGGAG 20 4395 BCL11A-3911 + GGGCCGGCCUGGGGACAGCG 20 4396 BCL11A-3912 + GCAUAGGGCUGGGCCGGCCU 20 4397 BCL11A-3913 − AUUAAGAAUCUACUUAGAAA 20 4398 BCL11A-3914 + CUAAACAGGGGGGGAGUGGG 20 4399 BCL11A-3915 + UUGACCGGGGGCUGGGAGGG 20 4400 BCL11A-3916 − CGCGGUCGUGGGCGUGGGCG 20 4401 BCL11A-3917 + GAGGGAGGGGGGGCGUCGCC 20 4402 BCL11A-3918 − GGAGAACGGGGACGAGGAGG 20 4403 BCL11A-3919 + CUUGACCGGGGGCUGGGAGG 20 4404 BCL11A-3920 + GGAGGGAGGGGGGGCGUCGC 20 4405 BCL11A-3921 + ACCGGGGGCUGGGAGGGAGG 20 4406 BCL11A-3922 − CGCAGCGGCACGGGAAGUGG 20 4407 BCL11A-3923 + GCGGAUUGCAGAGGAGGGAG 20 4408 BCL11A-3924 + GGAGGGGGGGCGUCGCCAGG 20 4409 BCL11A-3925 + GGCGGAUUGCAGAGGAGGGA 20 4410 BCL11A-3926 + GAGGGGCGGAUUGCAGAGGA 20 4411 BCL11A-3927 + GGGGCGGAUUGCAGAGGAGG 20 4412 BCL11A-3928 − GAGGAGCUGACGGAGAGCGA 20 4413 BCL11A-3929 + UCCGAAAACUGCCACACAUC 20 4414 BCL11A-3930 + CGGAUUGCAGAGGAGGGAGG 20 4415 BCL11A-3931 + GGAGGGGCGGAUUGCAGAGG 20 4416 BCL11A-3932 + GGGCGGAUUGCAGAGGAGGG 20 4417 BCL11A-3933 + AGGAGGGGCGGAUUGCAGAG 20 4418 BCL11A-3934 − AGAACGGGGACGAGGAGGAA 20 4419 BCL11A-3935 + GAGGGAGGAGGGGCGGAUUG 20 4420 BCL11A-3936 − UUGCGCUUCUCCACACCGCC 20 4421 BCL11A-3937 − AGCUGACGGAGAGCGAGAGG 20 4422 BCL11A-3938 − AGGAGGAGCUGACGGAGAGC 20 4423 BCL11A-3939 + GGGGCUGGGAGGGAGGAGGG 20 4424 BCL11A-3940 + GGGAGGAGGGGCGGAUUGCA 20 4425 BCL11A-3941 + CCGUGUUGGGCAUCGCGGCC 20 4426 BCL11A-3942 − GAACGGGGACGAGGAGGAAG 20 4427 BCL11A-3943 + GGAGGAGGGGCGGAUUGCAG 20 4428 BCL11A-3944 − GGAGGAGGAGCUGACGGAGA 20 4429 BCL11A-3945 − ACGGGGACGAGGAGGAAGAG 20 4430 BCL11A-3946 − AGGAGGAGGAGGAGCUGACG 20 4431 BCL11A-3947 − ACGACGAGGAAGAGGAAGAA 20 4432 BCL11A-3948 − ACGAGGAAGAGGAAGAAGAG 20 4433 BCL11A-3949 − AGGAGGAAGAGGAGGACGAC 20 4434 BCL11A-3950 − AAGAGGAGGACGACGAGGAA 20 4435 BCL11A-3951 − AGAGGAGGAGGAGGAGCUGA 20 4436 BCL11A-3952 − GGAGGAAGAGGAGGACGACG 20 4437 BCL11A-3953 − CGAGGAGGAAGAGGAGGACG 20 4438 BCL11A-3954 − CGAGGAAGAGGAAGAAGAGG 20 4439 BCL11A-3955 − AAGAGGAGGAGGAGGAGCUG 20 4440 BCL11A-3956 − CGACGAGGAAGAGGAAGAAG 20 4441 BCL11A-3957 − GGAGGACGACGAGGAAGAGG 20 4442 BCL11A-3958 − AGAGGAGGACGACGAGGAAG 20 4443 BCL11A-3959 − GGACGACGAGGAAGAGGAAG 20 4444 BCL11A-3960 − GGAAGAGGAGGACGACGAGG 20 4445 BCL11A-3961 − AGGAAGAAGAGGAGGAAGAG 20 4446 BCL11A-3962 − AAGAGGAAGAAGAGGAGGAA 20 4447 BCL11A-3963 − GGAAGAGGAAGAAGAGGAGG 20 4448 BCL11A-3964 − AAGAAGAGGAGGAAGAGGAG 20 4449 BCL11A-3965 − AAGAGGAGGAAGAGGAGGAG 20 4450 BCL11A-3966 − AGAGGAAGAAGAGGAGGAAG 20 4451 BCL11A-3967 − GGAAGAAGAGGAGGAAGAGG 20 4452 BCL11A-3968 − AGAAGAGGAGGAAGAGGAGG 20 4453 BCL11A-3969 − AGAGGAGGAAGAGGAGGAGG 20 4454 BCL11A-3970 + UCGGACUUGACCGUCAU 17 4455 BCL11A-3971 + GUCGGACUUGACCGUCA 17 4456 BCL11A-3972 + CGUCGGACUUGACCGUC 17 4457 BCL11A-3973 + CGGACUUGACCGUCAUG 17 4458 BCL11A-3974 − AUAUUAGUGGUCCGGGC 17 4459 BCL11A-3975 + GUCCGACUCGCCGGCCA 17 4460 BCL11A-3976 + CGAGGAGUGCUCCGACG 17 4461 BCL11A-3977 − CCAUUCGGCGUAGUACC 17 4462 BCL11A-3978 + CCGAGGAGUGCUCCGAC 17 4463 BCL11A-3979 − GCGGGUUGGUAUCCCUU 17 4464 BCL11A-3980 + AGUACACGUUCUCCGUG 17 4465 BCL11A-3981 − AUUCGGCGUAGUACCCA 17 4466 BCL11A-3982 + CGUGUUGGGCAUCGCGG 17 4467 BCL11A-3983 + CGCUUAUGCUUCUCGCC 17 4468 BCL11A-3984 − CGAAGACUCGGUGGCCG 17 4469 BCL11A-3985 − CCCACCGCAUAGAGCGC 17 4470 BCL11A-3986 + ACGCCGAAUGGGGGUGU 17 4471 BCL11A-3987 + GGCCCGGACCACUAAUA 17 4472 BCL11A-3988 + GUAGCCGGCGAGCCACU 17 4473 BCL11A-3989 − GAGCACUCCUCGGAGAA 17 4474 BCL11A-3990 − AGCACUCCUCGGAGAAC 17 4475 BCL11A-3991 + CUGGGUACUACGCCGAA 17 4476 BCL11A-3992 + CGCAGAACUCGCAUGAC 17 4477 BCL11A-3993 + ACCAACCCGCGGGGUCA 17 4478 BCL11A-3994 + UACCAACCCGCGGGGUC 17 4479 BCL11A-3995 + AUACCAACCCGCGGGGU 17 4480 BCL11A-3996 − CCACCGCAUAGAGCGCC 17 4481 BCL11A-3997 + UGGGGUCGUUCUCGCUC 17 4482 BCL11A-3998 − CGCCCCAUAUUAGUGGU 17 4483 BCL11A-3999 − GCGCAUCAAGCUCGAGA 17 4484 BCL11A-4000 + CUCCGAGGAGUGCUCCG 17 4485 BCL11A-4001 + CGAGCUUGAUGCGCUUA 17 4486 BCL11A-4002 − AGCGCAUCAAGCUCGAG 17 4487 BCL11A-4003 − GGAGCACUCCUCGGAGA 17 4488 BCL11A-4004 − CCGCGGCUGCUCCCCGG 17 4489 BCL11A-4005 − CACCGCAUAGAGCGCCU 17 4490 BCL11A-4006 + GAAGGGAUACCAACCCG 17 4491 BCL11A-4007 − CUUCUCCACACCGCCCG 17 4492 BCL11A-4008 − CCCUGCCCGACGUCAUG 17 4493 BCL11A-4009 − CCGGCACCAGCGACUUG 17 4494 BCL11A-4010 + UGGGUACUACGCCGAAU 17 4495 BCL11A-4011 + GUUCUCCGGGAUCAGGU 17 4496 BCL11A-4012 − CGACCCCAACCUGAUCC 17 4497 BCL11A-4013 + CCGAAUGGGGGUGUGUG 17 4498 BCL11A-4014 + GCUGGUGCCGGGUUCCG 17 4499 BCL11A-4015 − CGGGCGAGUCGGCCUCG 17 4500 BCL11A-4016 + UGCACCACCAGGUUGCU 17 4501 BCL11A-4017 − CACCACCGAGACAUCAC 17 4502 BCL11A-4018 − AUGGCCGCGGCUGCUCC 17 4503 BCL11A-4019 + UCUGGGUACUACGCCGA 17 4504 BCL11A-4020 + CAAACUCCCGUUCUCCG 17 4505 BCL11A-4021 + GGGCCCGGACCACUAAU 17 4506 BCL11A-4022 + CCCAGGCGCUCUAUGCG 17 4507 BCL11A-4023 − GCCUUUUGCCUCCUCGU 17 4508 BCL11A-4024 − CGUCGGAGCACUCCUCG 17 4509 BCL11A-4025 + CUUGAUGCGCUUAGAGA 17 4510 BCL11A-4026 + CGUUCUCCGGGAUCAGG 17 4511 BCL11A-4027 − CCGCGAUGCCCAACACG 17 4512 BCL11A-4028 + CCCCGAGGCCGACUCGC 17 4513 BCL11A-4029 − GGCCGCGAUGCCCAACA 17 4514 BCL11A-4030 − CUCGUCGGAGCACUCCU 17 4515 BCL11A-4031 + UCGGUGGUGGACUAAAC 17 4516 BCL11A-4032 + CAGGCGCUCUAUGCGGU 17 4517 BCL11A-4033 + CGCACAGGUUGCACUUG 17 4518 BCL11A-4034 + CGCUGGUGCCGGGUUCC 17 4519 BCL11A-4035 − GGUCAAGUCCAAGUCAU 17 4520 BCL11A-4036 − ACGACCCCAACCUGAUC 17 4521 BCL11A-4037 + GUGUUGGGCAUCGCGGC 17 4522 BCL11A-4038 − CCUCGUCGGAGCACUCC 17 4523 BCL11A-4039 − CUUGGACCCCCACCGCA 17 4524 BCL11A-4040 − AACCUGAUCCCGGAGAA 17 4525 BCL11A-4041 − ACGGCUUCGGGCUGAGC 17 4526 BCL11A-4042 − GCGCUUCUCCACACCGC 17 4527 BCL11A-4043 + UCGCUGGUGCCGGGUUC 17 4528 BCL11A-4044 − CAACCUGAUCCCGGAGA 17 4529 BCL11A-4045 − ACUCGGUGGCCGGCGAG 17 4530 BCL11A-4046 − CGGCCACCUGGCCGAGG 17 4531 BCL11A-4047 − CGCCUUUUGCCUCCUCG 17 4532 BCL11A-4048 − ACCCCAACCUGAUCCCG 17 4533 BCL11A-4049 − CCCGGAGAACGGGGACG 17 4534 BCL11A-4050 + GCAGGUCGAACUCCUUC 17 4535 BCL11A-4051 − CUAUGGAGCCUCCCGCC 17 4536 BCL11A-4052 + CCAGGCGCUCUAUGCGG 17 4537 BCL11A-4053 − GUUGAAUCCAAUGGCUA 17 4538 BCL11A-4054 − CGGCUUCGGGCUGAGCC 17 4539 BCL11A-4055 − GCUCGCGGGGCGCGGUC 17 4540 BCL11A-4056 − CCCUGUUUAGUCCACCA 17 4541 BCL11A-4057 + AUGACUUGGACUUGACC 17 4542 BCL11A-4058 − GGAAGUCCCCUGACCCC 17 4543 BCL11A-4059 − CCCGCCAUGGAUUUCUC 17 4544 BCL11A-4060 + CGGUGGUGGACUAAACA 17 4545 BCL11A-4061 + ACUUGGCCACCACGGAC 17 4546 BCL11A-4062 − CUCUAAGCGCAUCAAGC 17 4547 BCL11A-4063 + GCAAACUCCCGUUCUCC 17 4548 BCL11A-4064 + GUGGUGGACUAAACAGG 17 4549 BCL11A-4065 − CACCACGAGAACAGCUC 17 4550 BCL11A-4066 − CCGCCAUGGAUUUCUCU 17 4551 BCL11A-4067 + GCUUGAUGCGCUUAGAG 17 4552 BCL11A-4068 + CCCUGCAUGACGUCGGG 17 4553 BCL11A-4069 − CUAAGCGCAUCAAGCUC 17 4554 BCL11A-4070 + CAAGUGAUGUCUCGGUG 17 4555 BCL11A-4071 + CCGAGGCCGACUCGCCC 17 4556 BCL11A-4072 + CGAGGCCGACUCGCCCG 17 4557 BCL11A-4073 + AUUUGAACGUCUUGCCG 17 4558 BCL11A-4074 + GCUGCGUCUGCCCUCUU 17 4559 BCL11A-4075 − AGGCGGCGCGCCACCAC 17 4560 BCL11A-4076 + CUCGAGCUUGAUGCGCU 17 4561 BCL11A-4077 + GCGCAAACUCCCGUUCU 17 4562 BCL11A-4078 − AGAGGCUUCCGGCCUGG 17 4563 BCL11A-4079 − CCGGGCGAGUCGGCCUC 17 4564 BCL11A-4080 + GUCGCUGGUGCCGGGUU 17 4565 BCL11A-4081 − AGAGCGCCUGGGGGCGG 17 4566 BCL11A-4082 + GGUGGUGGACUAAACAG 17 4567 BCL11A-4083 + CCCGAGGCCGACUCGCC 17 4568 BCL11A-4084 − UUCUCUUGCAACACGCA 17 4569 BCL11A-4085 + UGGACUUGACCGGGGGC 17 4570 BCL11A-4086 − UCCCGGAGAACGGGGAC 17 4571 BCL11A-4087 + CUGGAGUCUCCGAAGCU 17 4572 BCL11A-4088 − GAUUUCUCUAGGAGACU 17 4573 BCL11A-4089 − GGUUGAAUCCAAUGGCU 17 4574 BCL11A-4090 − CCCGGGCGAGUCGGCCU 17 4575 BCL11A-4091 − GAUCCCGGAGAACGGGG 17 4576 BCL11A-4092 + CUCGGUGGUGGACUAAA 17 4577 BCL11A-4093 + UGGUGGACUAAACAGGG 17 4578 BCL11A-4094 + CCACCAAGUCGCUGGUG 17 4579 BCL11A-4095 − GGUGGCCAAGUUCAAGA 17 4580 BCL11A-4096 − CACCCGAGUGCCUUUGA 17 4581 BCL11A-4097 − GCAAGACGUUCAAAUUU 17 4582 BCL11A-4098 + GGCUCUCGAGCUUCCAU 17 4583 BCL11A-4099 + UGGAGUCUCCGAAGCUA 17 4584 BCL11A-4100 − CGGCCGCGAUGCCCAAC 17 4585 BCL11A-4101 + UCAAAGGCACUCGGGUG 17 4586 BCL11A-4102 + GGACUUGACCGGGGGCU 17 4587 BCL11A-4103 + UUGGACUUGACCGGGGG 17 4588 BCL11A-4104 + GUCUGCCCUCUUUUGAG 17 4589 BCL11A-4105 + GGCAAAAGGCGAUUGUC 17 4590 BCL11A-4106 − ACACGCACAGAACACUC 17 4591 BCL11A-4107 + GUAACCUUUGCAUAGGG 17 4592 BCL11A-4108 − UGCACCGGCGCAGCCAC 17 4593 BCL11A-4109 − UGGCCAAGUUCAAGAGC 17 4594 BCL11A-4110 − UAAGCGCGGCCACCUGG 17 4595 BCL11A-4111 + CAUAGGGCUGGGCCGGC 17 4596 BCL11A-4112 − ACCUGAUCCCGGAGAAC 17 4597 BCL11A-4113 − UGUGUGGCAGUUUUCGG 17 4598 BCL11A-4114 − UUUUCGGAUGGAAGCUC 17 4599 BCL11A-4115 − CCCCGGGCGAGUCGGCC 17 4600 BCL11A-4116 − UGGACUACGGCUUCGGG 17 4601 BCL11A-4117 − CCCUUCAGGACUAGGUG 17 4602 BCL11A-4118 − UCGGGGCGCAGCGGCAC 17 4603 BCL11A-4119 + UCUUGAACUUGGCCACC 17 4604 BCL11A-4120 − CCGGCGCAGCCACACGG 17 4605 BCL11A-4121 + UCUCGCCCAGGACCUGG 17 4606 BCL11A-4122 − CGGAGAACGGGGACGAG 17 4607 BCL11A-4123 + CACCCUGUCAAAGGCAC 17 4608 BCL11A-4124 + UCUGCACCUAGUCCUGA 17 4609 BCL11A-4125 − UAACCUGCUAAGAAUAC 17 4610 BCL11A-4126 − UCUCCACCGCCAGCUCC 17 4611 BCL11A-4127 − CUCCACCGCCAGCUCCC 17 4612 BCL11A-4128 + UUCUCGCCCAGGACCUG 17 4613 BCL11A-4129 + CCGCCUCCAGGCUCAGC 17 4614 BCL11A-4130 + UCCCUCCGUCCAGCUCC 17 4615 BCL11A-4131 − GAGGGUGGACUACGGCU 17 4616 BCL11A-4132 + CCAGCUCCCCGGGCGGU 17 4617 BCL11A-4133 + GCUCUCUAAGUCUCCUA 17 4618 BCL11A-4134 + CAUGACUUGGACUUGAC 17 4619 BCL11A-4135 + CCAUGCCCUGCAUGACG 17 4620 BCL11A-4136 + GCGAUUGUCUGGAGUCU 17 4621 BCL11A-4137 + UGGAGGCCGCGUAGCCG 17 4622 BCL11A-4138 − GCCACCUGGCCGAGGCC 17 4623 BCL11A-4139 − AUACCAGGAUCAGUAUC 17 4624 BCL11A-4140 − GUGUGGCAGUUUUCGGA 17 4625 BCL11A-4141 − CCACACCGCCCGGGGAG 17 4626 BCL11A-4142 − GGAGGCGGCGCGCCACC 17 4627 BCL11A-4143 + GUAUUCUUAGCAGGUUA 17 4628 BCL11A-4144 + AGAAGGGGCUCAGCGAG 17 4629 BCL11A-4145 + UGUUCUGUGCGUGUUGC 17 4630 BCL11A-4146 − AACCCCUUUAACCUGCU 17 4631 BCL11A-4147 + GCGCCCUUCUGCCAGGC 17 4632 BCL11A-4148 + CAGCUCCCCGGGCGGUG 17 4633 BCL11A-4149 + GGCGGCUUGCUACCUGG 17 4634 BCL11A-4150 + AGCGCCCUUCUGCCAGG 17 4635 BCL11A-4151 + GCGGCUUGCUACCUGGC 17 4636 BCL11A-4152 − GGGGCGCGGUCGUGGGC 17 4637 BCL11A-4153 − AGGCCUUCCACCAGGUC 17 4638 BCL11A-4154 + UCCCGUGCCGCUGCGCC 17 4639 BCL11A-4155 − CAGAACACUCAUGGAUU 17 4640 BCL11A-4156 + GCUCCCCGGGCGGUGUG 17 4641 BCL11A-4157 − GCCCGGGGAGCUGGACG 17 4642 BCL11A-4158 + UUGCAGUAACCUUUGCA 17 4643 BCL11A-4159 − AGACUUAGAGAGCUGGC 17 4644 BCL11A-4160 − GGCGCAGCCACACGGGC 17 4645 BCL11A-4161 + UUCUGCACCUAGUCCUG 17 4646 BCL11A-4162 + UUCUGUGCGUGUUGCAA 17 4647 BCL11A-4163 − CCCUGGCCACCCAUCAC 17 4648 BCL11A-4164 + AUAGGGCUGGGCCGGCC 17 4649 BCL11A-4165 − ACCAGGAUCAGUAUCGA 17 4650 BCL11A-4166 + UGAAGGGAUACCAACCC 17 4651 BCL11A-4167 + CUAGAGAAAUCCAUGGC 17 4652 BCL11A-4168 + CGGUGGAGAGACCGUCG 17 4653 BCL11A-4169 − UUUCUCUAGGAGACUUA 17 4654 BCL11A-4170 + GCAUGACUUGGACUUGA 17 4655 BCL11A-4171 − CUCGGGGCGCAGCGGCA 17 4656 BCL11A-4172 + GGUGGACUAAACAGGGG 17 4657 BCL11A-4173 + CCUCGCUGAAGUGCUGC 17 4658 BCL11A-4174 + CCAGGUUGCUCUGAAAU 17 4659 BCL11A-4175 − GCAUAGAGCGCCUGGGG 17 4660 BCL11A-4176 − GCAAGCUGAAGCGCCAC 17 4661 BCL11A-4177 + CUCGCUGAAGUGCUGCA 17 4662 BCL11A-4178 − GCACCCAGGCCAGCAAG 17 4663 BCL11A-4179 + GGGAGGCUCCAUAGCCA 17 4664 BCL11A-4180 + AGGCAAAAGGCGAUUGU 17 4665 BCL11A-4181 − GAUCCCUUCCUUAGCUU 17 4666 BCL11A-4182 + GUCUCCGAAGCUAAGGA 17 4667 BCL11A-4183 + CUUAGAGAAGGGGCUCA 17 4668 BCL11A-4184 + CUUUUUGGACAGGCCCC 17 4669 BCL11A-4185 + CUCGGGUGAUGGGUGGC 17 4670 BCL11A-4186 + GCCCACGACCGCGCCCC 17 4671 BCL11A-4187 + UUGUACAUGUGUAGCUG 17 4672 BCL11A-4188 − CCGUGGUGGCCAAGUUC 17 4673 BCL11A-4189 − GGAGAACGGGGACGAGG 17 4674 BCL11A-4190 − GCAGGCCCAGCUCAAAA 17 4675 BCL11A-4191 + UAUUCUUAGCAGGUUAA 17 4676 BCL11A-4192 + UCUGCAAUAUGAAUCCC 17 4677 BCL11A-4193 + UCCUAGAGAAAUCCAUG 17 4678 BCL11A-4194 + ACUUGACCGGGGGCUGG 17 4679 BCL11A-4195 + AGUCUCCGAAGCUAAGG 17 4680 BCL11A-4196 + GCUGGGCCUGCCCGGGC 17 4681 BCL11A-4197 − AGAUCCCUUCCUUAGCU 17 4682 BCL11A-4198 + CACACAUCUUGAGCUCU 17 4683 BCL11A-4199 − CCCGGGGAGCUGGACGG 17 4684 BCL11A-4200 + GAAGGGGCUCAGCGAGC 17 4685 BCL11A-4201 − GACUUAGAGAGCUGGCA 17 4686 BCL11A-4202 + UCCCAUGGAGAGGUGGC 17 4687 BCL11A-4203 + UGAAGUGCUGCAUGGAG 17 4688 BCL11A-4204 + ACAUUCUGCACCUAGUC 17 4689 BCL11A-4205 + CCCAUGGAGAGGUGGCU 17 4690 BCL11A-4206 + GCUCUCUGGGUACUACG 17 4691 BCL11A-4207 − CCACAGGGACACUUGCG 17 4692 BCL11A-4208 − GAGACUUAGAGAGCUGG 17 4693 BCL11A-4209 − UUGACAGGGUGCUGCGG 17 4694 BCL11A-4210 − CCGAGGCCGAGGGCCAC 17 4695 BCL11A-4211 + AGGGAUCUUUGAGCUGC 17 4696 BCL11A-4212 + AAGUAGAUUCUUAAUCC 17 4697 BCL11A-4213 − GCGCAGCGGCACGGGAA 17 4698 BCL11A-4214 − GCCGAGGCCGAGGGCCA 17 4699 BCL11A-4215 − AAGAUGUGUGGCAGUUU 17 4700 BCL11A-4216 + AGCUAAGGAAGGGAUCU 17 4701 BCL11A-4217 + CAGCUCUCUAAGUCUCC 17 4702 BCL11A-4218 + CCUAGAGAAAUCCAUGG 17 4703 BCL11A-4219 − ACCACGAGAACAGCUCG 17 4704 BCL11A-4220 + GCAAUAUGAAUCCCAUG 17 4705 BCL11A-4221 − CUCCAUGCAGCACUUCA 17 4706 BCL11A-4222 − UGUCCAAAAAGCUGCUG 17 4707 BCL11A-4223 − GAAUACCAGGAUCAGUA 17 4708 BCL11A-4224 − UCUCGGGGCGCAGCGGC 17 4709 BCL11A-4225 − AGUUUUCGGAUGGAAGC 17 4710 BCL11A-4226 − UCGUGGGCGUGGGCGAC 17 4711 BCL11A-4227 + UCGCGGCCGGGGGCAGG 17 4712 BCL11A-4228 − CUACUUAGAAAGCGAAC 17 4713 BCL11A-4229 + GGGUUAUUGUCUGCAAU 17 4714 BCL11A-4230 + CUUGACCGGGGGCUGGG 17 4715 BCL11A-4231 − UGGAUUAAGAAUCUACU 17 4716 BCL11A-4232 − GGCUUCCGGCCUGGCAG 17 4717 BCL11A-4233 − CUUCCACCAGGUCCUGG 17 4718 BCL11A-4234 + CGCUUCAGCUUGCUGGC 17 4719 BCL11A-4235 − CAUAGAGCGCCUGGGGG 17 4720 BCL11A-4236 + CCUGGUGGAAGGCCUCG 17 4721 BCL11A-4237 − UCCACCAGGUCCUGGGC 17 4722 BCL11A-4238 + CUGCAAUAUGAAUCCCA 17 4723 BCL11A-4239 − GCUGGACGGAGGGAUCU 17 4724 BCL11A-4240 + UUGACCGGGGGCUGGGA 17 4725 BCL11A-4241 − UUCCCAGCCACCUCUCC 17 4726 BCL11A-4242 + UUUUGAGCUGGGCCUGC 17 4727 BCL11A-4243 − GCUUCUCCACACCGCCC 17 4728 BCL11A-4244 + AGAGAAACCAUGCACUG 17 4729 BCL11A-4245 − AGCUGGACGGAGGGAUC 17 4730 BCL11A-4246 + CCGGGGAGCUGGCGGUG 17 4731 BCL11A-4247 + AUCCCAUGGAGAGGUGG 17 4732 BCL11A-4248 + GUUCCGGGGAGCUGGCG 17 4733 BCL11A-4249 + GACUAAACAGGGGGGGA 17 4734 BCL11A-4250 + UGCCCAGCAGCAGCUUU 17 4735 BCL11A-4251 + GGGAUCUUUGAGCUGCC 17 4736 BCL11A-4252 − UCCCAGCCACCUCUCCA 17 4737 BCL11A-4253 − CAGCGGCACGGGAAGUG 17 4738 BCL11A-4254 + UUCCGGGGAGCUGGCGG 17 4739 BCL11A-4255 + UCCUCGUCCCCGUUCUC 17 4740 BCL11A-4256 − GCGGCACGGGAAGUGGA 17 4741 BCL11A-4257 − UGGGCAGCCCCAGCUCG 17 4742 BCL11A-4258 − CGCAGCGGCACGGGAAG 17 4743 BCL11A-4259 − CCGCCCGGGGAGCUGGA 17 4744 BCL11A-4260 + AUGGAGAGGUGGCUGGG 17 4745 BCL11A-4261 + CUCCUCGUCCCCGUUCU 17 4746 BCL11A-4262 − UACUUAGAAAGCGAACA 17 4747 BCL11A-4263 − GGGCAGGCCCAGCUCAA 17 4748 BCL11A-4264 − ACCGCCCGGGGAGCUGG 17 4749 BCL11A-4265 + AAACAGGGGGGGAGUGG 17 4750 BCL11A-4266 + CGGGGGCUGGGAGGGAG 17 4751 BCL11A-4267 + CCGGCCUGGGGACAGCG 17 4752 BCL11A-4268 + UAGGGCUGGGCCGGCCU 17 4753 BCL11A-4269 − AAGAAUCUACUUAGAAA 17 4754 BCL11A-4270 + AACAGGGGGGGAGUGGG 17 4755 BCL11A-4271 + ACCGGGGGCUGGGAGGG 17 4756 BCL11A-4272 − GGUCGUGGGCGUGGGCG 17 4757 BCL11A-4273 + GGAGGGGGGGCGUCGCC 17 4758 BCL11A-4274 − GAACGGGGACGAGGAGG 17 4759 BCL11A-4275 + GACCGGGGGCUGGGAGG 17 4760 BCL11A-4276 + GGGAGGGGGGGCGUCGC 17 4761 BCL11A-4277 + GGGGGCUGGGAGGGAGG 17 4762 BCL11A-4278 − AGCGGCACGGGAAGUGG 17 4763 BCL11A-4279 + GAUUGCAGAGGAGGGAG 17 4764 BCL11A-4280 + GGGGGGGCGUCGCCAGG 17 4765 BCL11A-4281 + GGAUUGCAGAGGAGGGA 17 4766 BCL11A-4282 + GGGCGGAUUGCAGAGGA 17 4767 BCL11A-4283 + GCGGAUUGCAGAGGAGG 17 4768 BCL11A-4284 − GAGCUGACGGAGAGCGA 17 4769 BCL11A-4285 + GAAAACUGCCACACAUC 17 4770 BCL11A-4286 + AUUGCAGAGGAGGGAGG 17 4771 BCL11A-4287 + GGGGCGGAUUGCAGAGG 17 4772 BCL11A-4288 + CGGAUUGCAGAGGAGGG 17 4773 BCL11A-4289 + AGGGGCGGAUUGCAGAG 17 4774 BCL11A-4290 − ACGGGGACGAGGAGGAA 17 4775 BCL11A-4291 + GGAGGAGGGGCGGAUUG 17 4776 BCL11A-4292 − CGCUUCUCCACACCGCC 17 4777 BCL11A-4293 − UGACGGAGAGCGAGAGG 17 4778 BCL11A-4294 − AGGAGCUGACGGAGAGC 17 4779 BCL11A-4295 + GCUGGGAGGGAGGAGGG 17 4780 BCL11A-4296 + AGGAGGGGCGGAUUGCA 17 4781 BCL11A-4297 + UGUUGGGCAUCGCGGCC 17 4782 BCL11A-4298 − CGGGGACGAGGAGGAAG 17 4783 BCL11A-4299 + GGAGGGGCGGAUUGCAG 17 4784 BCL11A-4300 − GGAGGAGCUGACGGAGA 17 4785 BCL11A-4301 − GGGACGAGGAGGAAGAG 17 4786 BCL11A-4302 − AGGAGGAGGAGCUGACG 17 4787 BCL11A-4303 − ACGAGGAAGAGGAAGAA 17 4788 BCL11A-4304 − AGGAAGAGGAAGAAGAG 17 4789 BCL11A-4305 − AGGAAGAGGAGGACGAC 17 4790 BCL11A-4306 − AGGAGGACGACGAGGAA 17 4791 BCL11A-4307 − GGAGGAGGAGGAGCUGA 17 4792 BCL11A-4308 − GGAAGAGGAGGACGACG 17 4793 BCL11A-4309 − GGAGGAAGAGGAGGACG 17 4794 BCL11A-4310 − GGAAGAGGAAGAAGAGG 17 4795 BCL11A-4311 − AGGAGGAGGAGGAGCUG 17 4796 BCL11A-4312 − CGAGGAAGAGGAAGAAG 17 4797 BCL11A-4313 − GGACGACGAGGAAGAGG 17 4798 BCL11A-4314 − GGAGGACGACGAGGAAG 17 4799 BCL11A-4315 − CGACGAGGAAGAGGAAG 17 4800 BCL11A-4316 − AGAGGAGGACGACGAGG 17 4801 BCL11A-4317 − AAGAAGAGGAGGAAGAG 17 4802 BCL11A-4318 − AGGAAGAAGAGGAGGAA 17 4803 BCL11A-4319 − AGAGGAAGAAGAGGAGG 17 4804 BCL11A-4320 − AAGAGGAGGAAGAGGAG 17 4805 BCL11A-4321 − AGGAGGAAGAGGAGGAG 17 4806 BCL11A-4322 − GGAAGAAGAGGAGGAAG 17 4807 BCL11A-4323 − AGAAGAGGAGGAAGAGG 17 4808 BCL11A-4324 − AGAGGAGGAAGAGGAGG 17 4809 BCL11A-4325 − GGAGGAAGAGGAGGAGG 17 4810

Table 6A provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene selected according to first tier parameters. The targeting domains bind within first 500 bp of coding sequence downstream of start codon, good orthogonality, start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a N. meningitidis Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using N. meningitidis Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 6A Target SEQ 1st Tier DNA Site ID gRNA Name Strand Targeting Domain Length NO BCL11A-4326 + UUCUGCACUCAUCCCAGGCG 20 4811 BCL11A-4327 − AUCCAGGUCACGCCAGAGGA 20 4812 BCL11A-4328 + UGACCUGGAUGCCAACCUCC 20 4813 BCL11A-4329 + GGGAUUGGAUGCUUUUUUCA 20 4814 BCL11A-4330 + UGCACUCAUCCCAGGCG 17 4815 BCL11A-4331 − CAGGUCACGCCAGAGGA 17 4816 BCL11A-4332 + CCUGGAUGCCAACCUCC 17 4817 BCL11A-4333 + AUUGGAUGCUUUUUUCA 17 4818

Table 6B provides exemplary targeting domains for knocking out the BCL11A gene by targeting the early coding sequence the BCL11A gene. The targeting domains target outside the first 500 bp of coding sequence downstream of start codon. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a N. meningitidis Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using N. meningitidis Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 6B Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO BCL11A-4334 − GCUAUGGAGCCUCCCGC 17 4819 BCL11A-4335 + GACUUGACCGUCAUGGG 17 4820 BCL11A-4336 + UCCGACGAGGAGGCAAA 17 4821 BCL11A-4337 + CGGGAGGCUCCAUAGCC 17 4822 BCL11A-4338 + UCCGUGUUCGCUUUCUA 17 4823 BCL11A-4339 − AACACGCACAGAACACU 17 4824 BCL11A-4340 − UUCCCAGCCACCUCUCC 17 4825 BCL11A-4341 + GGCUGGGAGGGAGGAGG 17 4826 BCL11A-4342 + UCGGACUUGACCGUCAUGGG 20 4827 BCL11A-4343 − AUGGCUAUGGAGCCUCCCGC 20 4828 BCL11A-4344 + UGCUCCGACGAGGAGGCAAA 20 4829 BCL11A-4345 + UGGCGGGAGGCUCCAUAGCC 20 4830 BCL11A-4346 − UGCAACACGCACAGAACACU 20 4831 BCL11A-4347 + ACUUCCGUGUUCGCUUUCUA 20 4832 BCL11A-4348 − UCCUUCCCAGCCACCUCUCC 20 4833 BCL11A-4349 + GGGGGCUGGGAGGGAGGAGG 20 4834

Table 7A provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. Exemplary gRNA pairs are: BCL11A-5210 and BCL11A-5204, BCL11A-5211 and BCL11A-5204, BCL11A-5172 and BCL11A-5176, BCL11A-5172 and BCL11A-5186, BCL11A-5179 and BCL11A-5176, or BCL11A-5179 and BCL11A-5186.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene. For example, gRNA pairs that target upstream (i.e., 5′) of the enhancer region in the BCL11A gene (e.g., BCL11A-5210 and BCL11A-5204, or BCL11A-5211 and BCL11A-5204) can be paired with gRNA pairs that target downstream (i.e., 3′) of the enhancer region in the BCL11A gene (e.g., BCL11A-5172 and BCL11A-5176, BCL11A-5172 and BCL11A-5186, BCL11A-5179 and BCL11A-5176, or BCL11A-5179 and BCL11A-5186).

TABLE 7A Target 5′ or SEQ 1st Tier DNA Targeting Site 3′ of ID gRNA Name Strand Domain Length repeats NO BCL11A-5172 + GAAAAUACUU 20 3′ 4835 ACUGUACUGC BCL11A-5173 − GAAAGCAGUG 17 5′ 4836 UAAGGCU BCL11A-5174 − GGCUGUUUUG 20 5′ 4837 GAAUGUAGAG BCL11A-5175 + GUGCUACUUA 20 3′ 4838 UACAAUUCAC

Table 7B provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to second tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. The table provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 7B Target 2nd Tier DNA Site 5′ or 3′ of SEQ ID gRNA Name Strand Targeting Domain Length repeats NO BCL11A-5176 − AAACUAUUUACAGCCAUAAC 20 3′ 4839 BCL11A-5177 + AAAUACUUACUGUACUGCAG 20 3′ 4840 BCL11A-5178 − AACUAUUUACAGCCAUAACA 20 3′ 4841 BCL11A-5179 + AAUACUUACUGUACUGC 17 3′ 4842 BCL11A-5180 + ACAACUUGUGUUGCACU 17 5′ 4843 BCL11A-5181 + AUACUUACUGUACUGCA 17 3′ 4844 BCL11A-5182 + AUUCACUGGAAACCCUGUUA 20 3′ 4845 BCL11A-5183 + AUUUAAGACGGGAAAAC 17 5′ 4846 BCL11A-5184 + CACUGGAAACCCUGUUA 17 3′ 4847 BCL11A-5185 + CUACUUAUACAAUUCAC 17 3′ 4848 BCL11A-5186 − CUAUUUACAGCCAUAAC 17 3′ 4849 BCL11A-5187 − UAAGAAAGCAGUGUAAGGCU 20 5′ 4850 BCL11A-5188 + UACACAACUUGUGUUGCACU 20 5′ 4851 BCL11A-5189 + UACUGUACUGCAGGGGAAUU 20 3′ 4852 BCL11A-5190 + UACUUACUGUACUGCAG 17 3′ 4853 BCL11A-5191 + UGUACUGCAGGGGAAUU 17 3′ 4854

Table 7C provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to third tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer and start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. The table provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 7C Target 3rd Tier DNA Site 5′ or 3′ of SEQ ID gRNA Name Strand Targeting Domain Length repeats NO BCL11A-5192 − GAAUGUAGAGAGGCAGA 17 5′ 4855 BCL11A-5193 − GGAAUGUAGAGAGGCAG 17 5′ 4856 BCL11A-5194 − GUAAGUAUUUUCUUUCAUUG 20 3′ 4857 BCL11A-5195 − GUAAUUAAGAAAGCAGUGUA 20 5′ 4858 BCL11A-5196 − GUAUUUUCUUUCAUUGG 17 3′ 4859

Table 7D provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to forth tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. The table provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 7D Target 4th Tier DNA Site 5′ or 3′ of SEQ ID gRNA Name Strand Targeting Domain Length repeats NO BCL11A-5197 − AAAAUAAUUAGAAUAAA 17 5′ 4860 BCL11A-5198 + AAAAUACUUACUGUACUGCA 20 3′ 4861 BCL11A-5199 + AAAAUUUAAGACGGGAAAAC 20 5′ 4862 BCL11A-5200 − AAGUAUUUUCUUUCAUU 17 3′ 4863 BCL11A-5201 − AAUGUAGAGAGGCAGAG 17 5′ 4864 BCL11A-5202 + ACAUAAAAAUUUAAGAC 17 5′ 4865 BCL11A-5203 − AGAAAGCAGUGUAAGGC 17 5′ 4866 BCL11A-5204 − AGAAUAAAAGGCUGUUU 17 5′ 4867 BCL11A-5205 − AGUAAAAUAAUUAGAAUAAA 20 5′ 4868 BCL11A-5206 − AGUAAGUAUUUUCUUUCAUU 20 3′ 4869 BCL11A-5207 − AGUAUUUUCUUUCAUUG 17 3′ 4870 BCL11A-5208 − AUUAAGAAAGCAGUGUA 17 5′ 4871 BCL11A-5209 − AUUAGAAUAAAAGGCUGUUU 20 5′ 4872 BCL11A-5210 + AUUAUUUUACUAGUGAAUUA 20 5′ 4873 BCL11A-5211 + AUUUUACUAGUGAAUUA 17 5′ 4874 BCL11A-5212 + CACAUAAAAAUUUAAGA 17 5′ 4875 BCL11A-5213 − CAGUAAGUAUUUUCUUUCAU 20 3′ 4876 BCL11A-5214 + CUCACAUAAAAAUUUAAGAC 20 5′ 4877 BCL11A-5215 − UAAGUAUUUUCUUUCAU 17 3′ 4878 BCL11A-5216 − UAAGUAUUUUCUUUCAUUGG 20 3′ 4879 BCL11A-5217 − UAUUUACAGCCAUAACA 17 3′ 4880 BCL11A-5218 + UCUCACAUAAAAAUUUAAGA 20 5′ 4881 BCL11A-5219 − UGGAAUGUAGAGAGGCAGAG 20 5′ 4882 BCL11A-5220 − UGUUUUGGAAUGUAGAG 17 5′ 4883 BCL11A-5221 − UUAAGAAAGCAGUGUAAGGC 20 5′ 4884 BCL11A-5222 − UUGGAAUGUAGAGAGGCAGA 20 5′ 4885 BCL11A-5223 − UUUGGAAUGUAGAGAGGCAG 20 5′ 4886

Table 8A provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TS S) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 8A Target 1st Tier DNA Site 5′ or 3′ of SEQ ID gRNA Name Strand Targeting Domain Length repeats NO BCL11A-5224 − GAGGGGCUGAUAUAACUUCU 20 5′ 4887 BCL11A-5225 + GCUACUUAUACAAUUCA 17 3′ 4888 BCL11A-5226 − GGGCUGAUAUAACUUCU 17 5′ 4889 BCL11A-5227 − GUCUUAAAUUUUUAUGUGAG 20 5′ 4890 BCL11A-5228 + GUGCUACUUAUACAAUUCAC 20 3′ 4891

Table 8B provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to second tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. The table provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 8B Target 2nd Tier DNA Site 5′ or 3′ of SEQ ID gRNA Name Strand Targeting Domain Length repeats NO BCL11A-5229 − AACACAAGUUGUGUAGA 17 5′ 4892 BCL11A-5230 − ACUAUUUACAGCCAUAA 17 3′ 4893 BCL11A-5231 − AGCACACUGCUGUAAUU 17 5′ 4894 BCL11A-5232 + AGUGCUACUUAUACAAUUCA 20 3′ 4895 BCL11A-5233 + AUAGUUUGCUUCCCCCA 17 3′ 4896 BCL11A-5234 − AUGAGCACACUGCUGUAAUU 20 5′ 4897 BCL11A-5235 − CAAACUAUUUACAGCCAUAA 20 3′ 4898 BCL11A-5236 − CAGCCAUAACAGGGUUUCCA 20 3′ 4899 BCL11A-5237 − CCAUAACAGGGUUUCCA 17 3′ 4900 BCL11A-5238 + CUACUUAUACAAUUCAC 17 3′ 4901 BCL11A-5239 − CUUUGGCUAUUGAUACUGAU 20 3′ 4902 BCL11A-5240 + UAAAUAGUUUGCUUCCCCCA 20 3′ 4903 BCL11A-5241 + UAGUUUGCUUCCCCCAAUGA 20 3′ 4904 BCL11A-5242 − UGCAACACAAGUUGUGUAGA 20 5′ 4905 BCL11A-5243 − UGGAAUGUAGAGAGGCA 17 5′ 4906 BCL11A-5244 − UGGCUAUUGAUACUGAU 17 3′ 4907 BCL11A-5245 + UUUGCUUCCCCCAAUGA 17 3′ 4908 BCL11A-5246 − UUUUGGAAUGUAGAGAGGCA 20 5′ 4909

Table 8C provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to third tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TS S) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer and start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. The table provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 8C Target 3rd Tier DNA Site 5′ or 3′ of SEQ ID gRNA Name Strand Targeting Domain Length repeats NO BCL11A-5247 + GAAAAUACUUACUGUACUGC 20 3′ 4910 BCL11A-5248 − GAAUUGUAUAAGUAGCA 17 3′ 4911 BCL11A-5249 − GAGUUCUGUGUCAGCAAAAA 20 3′ 4912 BCL11A-5250 + GGAAAACAGGAAGAUGCAUU 20 5′ 4913 BCL11A-5251 − GGAAUGUAGAGAGGCAG 17 5′ 4914 BCL11A-5252 − GGCUGUUUUGGAAUGUA 17 5′ 4915 BCL11A-5253 − GUAAGUAUUUUCUUUCA 17 3′ 4916 BCL11A-5254 − GUAAGUAUUUUCUUUCAUUG 20 3′ 4917 BCL11A-5255 − GUAUUUUCUUUCAUUGG 17 3′ 4918

Table 8D provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to forth tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. The table provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 8D Target 4th Tier DNA Site 5′ or 3′ of SEQ ID gRNA Name Strand Targeting Domain Length repeats NO BCL11A-5256 + AAAAAUUUAAGACGGGAAAA 20 5′ 4919 BCL11A-5257 + AAAACAGGAAGAUGCAUUCU 20 5′ 4920 BCL11A-5258 − AAAACUAGAAAGUUUUA 17 3′ 4921 BCL11A-5259 + AAAAUACUUACUGUACUGCA 20 3′ 4922 BCL11A-5260 + AAAAUUUAAGACGGGAAAAC 20 5′ 4923 BCL11A-5261 + AAACAGGAAGAUGCAUU 17 5′ 4924 BCL11A-5262 − AAAGGCUGUUUUGGAAUGUA 20 5′ 4925 BCL11A-5263 + AAAUACUUACUGUACUG 17 3′ 4926 BCL11A-5264 + AAAUACUUACUGUACUGCAG 20 3′ 4927 BCL11A-5265 − AAGAAAGCAGUGUAAGG 17 5′ 4928 BCL11A-5266 − AAGGCUGUUUUGGAAUG 17 5′ 4929 BCL11A-5267 − AAGUAUUUUCUUUCAUU 17 3′ 4930 BCL11A-5268 + AAUACUUACUGUACUGC 17 3′ 4931 BCL11A-5269 − AAUUAGAAUAAAAGGCUGUU 20 5′ 4932 BCL11A-5270 + AAUUAUUUUACUAGUGAAUU 20 5′ 4933 BCL11A-5271 + AAUUUAAGACGGGAAAA 17 5′ 4934 BCL11A-5272 + ACAGGAAGAUGCAUUCU 17 5′ 4935 BCL11A-5273 − ACAGUAAGUAUUUUCUUUCA 20 3′ 4936 BCL11A-5274 + ACAUAAAAAUUUAAGAC 17 5′ 4937 BCL11A-5275 + ACUUUCUAGUUUUGCUUAAC 20 3′ 4938 BCL11A-5276 + AGAAAAUACUUACUGUACUG 20 3′ 4939 BCL11A-5277 − AGAAUAAAAGGCUGUUU 17 5′ 4940 BCL11A-5278 − AGCAAAACUAGAAAGUUUUA 20 3′ 4941 BCL11A-5279 − AGUAAGUAUUUUCUUUCAUU 20 3′ 4942 BCL11A-5280 − AGUAUUUUCUUUCAUUG 17 3′ 4943 BCL11A-5281 − AGUGAAUUGUAUAAGUAGCA 20 3′ 4944 BCL11A-5282 + AUACUUACUGUACUGCA 17 3′ 4945 BCL11A-5283 + AUCUCACAUAAAAAUUUAAG 20 5′ 4946 BCL11A-5284 − AUUAAGAAAGCAGUGUAAGG 20 5′ 4947 BCL11A-5285 − AUUAGAAUAAAAGGCUGUUU 20 5′ 4948 BCL11A-5286 + AUUAUUUUACUAGUGAAUUA 20 5′ 4949 BCL11A-5287 + AUUUAAGACGGGAAAAC 17 5′ 4950 BCL11A-5288 + AUUUUACUAGUGAAUUA 17 5′ 4951 BCL11A-5289 − AUUUUCAUGUUAAGCAAAAC 20 3′ 4952 BCL11A-5290 + CACAUAAAAAUUUAAGA 17 5′ 4953 BCL11A-5291 − CAGUAAGUAUUUUCUUUCAU 20 3′ 4954 BCL11A-5292 − CCGUCUUAAAUUUUUAU 17 5′ 4955 BCL11A-5293 + CUCACAUAAAAAUUUAAGAC 20 5′ 4956 BCL11A-5294 − UAAAAGGCUGUUUUGGAAUG 20 5′ 4957 BCL11A-5295 − UAAGUAUUUUCUUUCAU 17 3′ 4958 BCL11A-5296 − UAAGUAUUUUCUUUCAUUGG 20 3′ 4959 BCL11A-5297 − UAAUUCACUAGUAAAAUAAU 20 5′ 4960 BCL11A-5298 + UACUUACUGUACUGCAG 17 3′ 4961 BCL11A-5299 − UAGAAUAAAAGGCUGUU 17 5′ 4962 BCL11A-5300 + UAUUUUACUAGUGAAUU 17 5′ 4963 BCL11A-5301 + UCACAUAAAAAUUUAAG 17 5′ 4964 BCL11A-5302 + UCUCACAUAAAAAUUUAAGA 20 5′ 4965 BCL11A-5303 + UGUUUCAUUUUUUGCUGACA 20 3′ 4966 BCL11A-5304 − UGUUUUGGAAUGUAGAGAGG 20 5′ 4967 BCL11A-5305 − UUAAAUUUUUAUGUGAG 17 5′ 4968 BCL11A-5306 + UUAUUCUAAUUAUUUUACUA 20 5′ 4969 BCL11A-5307 − UUCACUAGUAAAAUAAU 17 5′ 4970 BCL11A-5308 − UUCAUGUUAAGCAAAAC 17 3′ 4971 BCL11A-5309 + UUCAUUUUUUGCUGACA 17 3′ 4972 BCL11A-5310 − UUCCCGUCUUAAAUUUUUAU 20 5′ 4973 BCL11A-5311 + UUCUAAUUAUUUUACUA 17 5′ 4974 BCL11A-5312 + UUCUAGUUUUGCUUAAC 17 3′ 4975 BCL11A-5313 − UUCUGUGUCAGCAAAAA 17 3′ 4976 BCL11A-5314 − UUUGGAAUGUAGAGAGG 17 5′ 4977 BCL11A-5315 − UUUGGAAUGUAGAGAGGCAG 20 5′ 4978

Table 9 provides exemplary targeting domains for removing (e.g., deleting) the enhancer region in the BCL11A gene selected according to first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of transcription start site, TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) of enhancer, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase). In an embodiment, dual targeting is used to create two double strand breaks to remove the enhancer region in the BCL11A gene, e.g., the first gRNA is used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second gRNA is used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

Any of the targeting domains in the table can be used with a N. meningitidis Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using N. meningitidis Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

In an embodiment, four gRNAs (e.g., two pairs) are used to target four Cas9 nickases to create four nicks to remove the enhancer region in the BCL11A gene, e.g., the first pair of gRNAs are used to target upstream (i.e., 5′) of the enhancer region in the BCL11A gene and the second pair of gRNAs are used to target downstream (i.e., 3′) of the enhancer region in the BCL11A gene.

TABLE 9 Target 1st Tier DNA Site 5′ or 3′ of SEQ ID gRNA Name Strand Targeting Domain Length repeats NO BCL11A-5316 − UUUGGAUCUUUGGCUAUUGA 20 3′ 4979 BCL11A-5317 − GGAUCUUUGGCUAUUGA 17 3′ 4980

Table 10A provides exemplary targeting domains for knocking down expression of the BCL11A gene according to first tier parameters. The targeting domains bind between 500 bp upstream and 500 bp downstream of transcription start site, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes eiCas9 molecule to cause a steric block at the target region, e.g., between 500 bp upstream and 500 bp downstream of transcription start site to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a S. pyogenes eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 10A 1st Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-4350 + GACGACGGCUCGGUUCACAU 20 4981 BCL11A-4351 + GACGCCAGACGCGGCCCCCG 20 4982 BCL11A-4352 + GCCUUGCUUGCGGCGAGACA 20 4983 BCL11A-4353 + GGCUCCGCGGACGCCAGACG 20 4984 BCL11A-4354 + GACGGCUCGGUUCACAU 17 4985 BCL11A-4355 − GCCGCGUCUGGCGUCCG 17 4986 BCL11A-4356 + GCGGGCGGACGACGGCU 17 4987

Table 10B provides exemplary targeting domains for knocking down expression of the BCL11A gene according to second tier parameters. The targeting domains bind between 500 bp upstream and 500 bp downstream of transcription start site, good orthogonality and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes eiCas9 molecule to cause a steric block at the target region, e.g., between 500 bp upstream and 500 bp downstream of transcription start site to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a S. pyogenes eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 10B 2nd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-4357 + ACACGGCAAUGGUUCCAGAU 20 4988 BCL11A-4358 − ACCAUGUCUCGCCGCAAGCA 20 4989 BCL11A-4359 + ACGACGGCUCGGUUCACAUC 20 4990 BCL11A-4360 + AUUCCCGUUUGCUUAAGUGC 20 4991 BCL11A-4361 − CAUUUUAGAGUCCGCGUGUG 20 4992 BCL11A-4362 + CGGACGCCAGACGCGGCCCC 20 4993 BCL11A-4363 + CGGUUCACAUCGGGAGAGCC 20 4994 BCL11A-4364 − CUCCUGACGUUCAAGUUCGC 20 4995 BCL11A-4365 − UAAUAAUCACGAGAGCGCGC 20 4996 BCL11A-4366 − UCCUGACGUUCAAGUUCGCA 20 4997 BCL11A-4367 + UCGGUUCACAUCGGGAGAGC 20 4998 BCL11A-4368 + UCUUUUACCUCGACUCUCGG 20 4999 BCL11A-4369 + UGCUUGCGGCGAGACAUGGU 20 5000 BCL11A-4370 − UUUAGAGUCCGCGUGUGUGG 20 5001 BCL11A-4371 + ACGGCUCGGUUCACAUC 17 5002 BCL11A-4372 − AUGUCUCGCCGCAAGCA 17 5003 BCL11A-4373 − CUGACGUUCAAGUUCGC 17 5004 BCL11A-4374 − UAAUCACGAGAGCGCGC 17 5005 BCL11A-4375 + UCCGCGGACGCCAGACG 17 5006 BCL11A-4376 − UGACGUUCAAGUUCGCA 17 5007 BCL11A-4377 − UUAGAGUCCGCGUGUGU 17 5008 BCL11A-4378 + UUGCGGCGAGACAUGGU 17 5009 BCL11A-4379 + UUGCUUGCGGCGAGACA 17 5010 BCL11A-4380 + UUUACCUCGACUCUCGG 17 5011 BCL11A-4381 − UUUAGAGUCCGCGUGUG 17 5012

Table 10C provides exemplary targeting domains for knocking down expression of the BCL11A gene according to third tier parameters. The targeting domains bind between 500 bp upstream and 500 bp downstream of transcription start site and start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes eiCas9 molecule to cause a steric block at the target region, e.g., between 500 bp upstream and 500 bp downstream of transcription start site to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a S. pyogenes eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 10C 3rd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-4382 − GAAAAAACCCUCAUCCCAUC 20 5013 BCL11A-4383 + GAAAGGGGUGGCAGGGG 17 5014 BCL11A-4384 + GAACUUGAACGUCAGGAGUC 20 5015 BCL11A-4385 − GAACUUGCAGCUCAGGG 17 5016 BCL11A-4386 + GAAGAAAGGGGUGGCAG 17 5017 BCL11A-4387 + GAAGAAAGGGGUGGCAGGGG 20 5018 BCL11A-4388 + GAAGGGGAAGCUCACACCAA 20 5019 BCL11A-4389 + GAAGGGGAGGAGGGAAG 17 5020 BCL11A-4390 + GAAUUGUGGGAGAGCCGUCA 20 5021 BCL11A-4391 + GACAAGCCAAUGGCCAGUGC 20 5022 BCL11A-4392 + GACAGAGACACACAAAACAU 20 5023 BCL11A-4393 + GACAUGAAAAAGAGACC 17 5024 BCL11A-4394 + GACAUGGUGGGCUGCGGGGC 20 5025 BCL11A-4395 + GACGCGGCCCCCGGGGG 17 5026 BCL11A-4396 − GACUAGAAGCAAAAGCG 17 5027 BCL11A-4397 − GACUAGAAGCAAAAGCGAGG 20 5028 BCL11A-4398 + GAGAAGAAAGGGGUGGC 17 5029 BCL11A-4399 + GAGAAGGGGAGGAGGGA 17 5030 BCL11A-4400 + GAGACACACAAAACAUGGGC 20 5031 BCL11A-4401 + GAGACAUGGUGGGCUGC 17 5032 BCL11A-4402 + GAGAGAAGAAAGGGGUGGCA 20 5033 BCL11A-4403 + GAGAGAAGAGAGAUAGA 17 5034 BCL11A-4404 + GAGAGAAGGGGAGGAGGGAA 20 5035 BCL11A-4405 + GAGAGAGAGAAGAGAGAUAG 20 5036 BCL11A-4406 + GAGAGAGAUGAAAAAAA 17 5037 BCL11A-4407 + GAGCAGGAGAGAAGGGG 17 5038 BCL11A-4408 + GAGCAGGAGAGAAGGGGAGG 20 5039 BCL11A-4409 + GAGCCGGGUUAGAAAGA 17 5040 BCL11A-4410 + GAGGGGAGGGGGCGCUG 17 5041 BCL11A-4411 + GAGGGGCGGGCCGAGGGGAG 20 5042 BCL11A-4412 + GAGGGGGAGGUGCGGGG 17 5043 BCL11A-4413 + GAGGGGGAGGUGCGGGGCGG 20 5044 BCL11A-4414 − GAGGUAAAAGAGAUAAA 17 5045 BCL11A-4415 − GAGUCCGCGUGUGUGGG 17 5046 BCL11A-4416 − GAGUCUCCUUCUUUCUAACC 20 5047 BCL11A-4417 − GAUGAAGAUAUUUUCUC 17 5048 BCL11A-4418 − GCAAAAGCGAGGGGGAGAGA 20 5049 BCL11A-4419 − GCACCUCCCCCUCCCCGCAC 20 5050 BCL11A-4420 − GCACUUGAACUUGCAGCUCA 20 5051 BCL11A-4421 + GCAGGGAAGAUGAAUUG 17 5052 BCL11A-4422 + GCAGGGCGAGCAGGAGAGAA 20 5053 BCL11A-4423 + GCAGGGGUGGGAGGAAA 17 5054 BCL11A-4424 + GCAGGGGUGGGAGGAAAGGG 20 5055 BCL11A-4425 + GCCAAUGGCCAGUGCGGGGA 20 5056 BCL11A-4426 − GCCACCCCUUUCUUCUCUCC 20 5057 BCL11A-4427 + GCCAGACGCGGCCCCCG 17 5058 BCL11A-4428 − GCCCCAGCGCCCCCUCCCCU 20 5059 BCL11A-4429 + GCCCCCGGGGGAGGGGC 17 5060 BCL11A-4430 − GCCCGCCCCUCCCCCGG 17 5061 BCL11A-4431 + GCCGAGGGGAGGGGGCGCUG 20 5062 BCL11A-4432 + GCCGCGGCGGUGGCGUGGCC 20 5063 BCL11A-4433 + GCCGGGAGAGAAGAAAG 17 5064 BCL11A-4434 + GCCGGGAGAGAAGAAAGGGG 20 5065 BCL11A-4435 + GCGAGACAUGGUGGGCUGCG 20 5066 BCL11A-4436 + GCGCAGGGAAGAUGAAUUGU 20 5067 BCL11A-4437 + GCGCCGCGGCGGUGGCG 17 5068 BCL11A-4438 − GCGCUCGCUGCGGCCAC 17 5069 BCL11A-4439 + GCGGCCCCCGGGGGAGGGGC 20 5070 BCL11A-4440 − GCGGCGCUCGCUGCGGCCAC 20 5071 BCL11A-4441 + GCGGCGGCGGCGGCGGC 17 5072 BCL11A-4442 + GCGGCGGCGGCGGCGGCGGC 20 5073 BCL11A-4443 + GCGGCGGCGGCGGCGGCGGG 20 5074 BCL11A-4444 + GCGGCGGCGGCGGCGGG 17 5075 BCL11A-4445 + GCGGCGGGCGGACGACGGCU 20 5076 BCL11A-4446 + GCGGCGGUGGCGUGGCC 17 5077 BCL11A-4447 + GCGGGCGGCGGCGGCGG 17 5078 BCL11A-4448 + GCGGGCGGCGGCGGCGGCGG 20 5079 BCL11A-4449 + GCGGGGAGGGGGAGGUG 17 5080 BCL11A-4450 + GCGUGGCCGGGAGAGAAGAA 20 5081 BCL11A-4451 + GCUCCCCCCCACACACG 17 5082 BCL11A-4452 + GCUGGGGUUUGCCUUGCUUG 20 5083 BCL11A-4453 + GGACAAGCCAAUGGCCAGUG 20 5084 BCL11A-4454 + GGACACACAUCAGGGGC 17 5085 BCL11A-4455 + GGACAGAGACACACAAAACA 20 5086 BCL11A-4456 + GGACGCCAGACGCGGCCCCC 20 5087 BCL11A-4457 − GGACUAGAAGCAAAAGCGAG 20 5088 BCL11A-4458 + GGAGAGAAGAAAGGGGUGGC 20 5089 BCL11A-4459 + GGAGAGAAGGGGAGGAGGGA 20 5090 BCL11A-4460 + GGAGAGCCGGGUUAGAAAGA 20 5091 BCL11A-4461 + GGAGGGGCGGGCCGAGGGGA 20 5092 BCL11A-4462 + GGAGGGGGAGGUGCGGGGCG 20 5093 BCL11A-4463 + GGAGGGGGCGCUGGGGCCGC 20 5094 BCL11A-4464 + GGCAGGGCGAGCAGGAGAGA 20 5095 BCL11A-4465 + GGCAGGGGUGGGAGGAA 17 5096 BCL11A-4466 − GGCCACUGGUGAGCCCG 17 5097 BCL11A-4467 + GGCCCCCGGGGGAGGGG 17 5098 BCL11A-4468 − GGCCCGCCCCUCCCCCG 17 5099 BCL11A-4469 + GGCCGAGGGGAGGGGGCGCU 20 5100 BCL11A-4470 + GGCCGCAGCGAGCGCCG 17 5101 BCL11A-4471 + GGCCGCAGCGAGCGCCGCGG 20 5102 BCL11A-4472 + GGCCGCGGGCUCACCAG 17 5103 BCL11A-4473 + GGCCGGGAGAGAAGAAA 17 5104 BCL11A-4474 + GGCGAGACAUGGUGGGCUGC 20 5105 BCL11A-4475 + GGCGAGCAGGAGAGAAG 17 5106 BCL11A-4476 + GGCGAGCAGGAGAGAAGGGG 20 5107 BCL11A-4477 + GGCGCAGGGAAGAUGAAUUG 20 5108 BCL11A-4478 + GGCGGCGGCGGCGGCGG 17 5109 BCL11A-4479 + GGCGGCGGCGGCGGCGGCGG 20 5110 BCL11A-4480 + GGCGGGCCGAGGGGAGG 17 5111 BCL11A-4481 + GGCUGCGGGGCGGGCGG 17 5112 BCL11A-4482 + GGCUGCGGGGCGGGCGGCGG 20 5113 BCL11A-4483 + GGGAGAGAAGAAAGGGG 17 5114 BCL11A-4484 + GGGAGGAAAGGGUGGGG 17 5115 BCL11A-4485 + GGGAGGGGCGGGCCGAG 17 5116 BCL11A-4486 + GGGAGGGGCGGGCCGAGGGG 20 5117 BCL11A-4487 + GGGAGGGGGAGGUGCGGGGC 20 5118 BCL11A-4488 + GGGAGGGGGCGCUGGGGCCG 20 5119 BCL11A-4489 + GGGAGGUGCGGGGCGGG 17 5120 BCL11A-4490 + GGGCCGAGGGGAGGGGGCGC 20 5121 BCL11A-4491 + GGGCGAGCAGGAGAGAA 17 5122 BCL11A-4492 + GGGCGGGCCGAGGGGAG 17 5123 BCL11A-4493 + GGGGAAGCUCACACCAA 17 5124 BCL11A-4494 + GGGGAGGGGCGGGCCGA 17 5125 BCL11A-4495 + GGGGAGGGGGAGGUGCG 17 5126 BCL11A-4496 + GGGGAGGGGGAGGUGCGGGG 20 5127 BCL11A-4497 + GGGGAGGUGCGGGGCGG 17 5128 BCL11A-4498 − GGGGCCGCGUCUGGCGUCCG 20 5129 BCL11A-4499 + GGGGCGGGCCGAGGGGA 17 5130 BCL11A-4500 + GGGGCGGGCGGCGGCGG 17 5131 BCL11A-4501 + GGGGCGGGCGGCGGCGGCGG 20 5132 BCL11A-4502 + GGGGGAGGGGCGGGCCG 17 5133 BCL11A-4503 + GGGGGAGGUGCGGGGCG 17 5134 BCL11A-4504 + GGGGGCGCUGGGGCCGC 17 5135 BCL11A-4505 + GGGGUGGCAGGGGUGGG 17 5136 BCL11A-4506 + GGGGUGGGAGGAAAGGG 17 5137 BCL11A-4507 + GGGGUGGGAGGAAAGGGUGG 20 5138 BCL11A-4508 + GGGGUUUGCCUUGCUUG 17 5139 BCL11A-4509 + GGGUGGGAGGAAAGGGU 17 5140 BCL11A-4510 + GGGUGGGAGGAAAGGGUGGG 20 5141 BCL11A-4511 − GGUAAAAGAGAUAAAGG 17 5142 BCL11A-4512 + GGUGGCAGGGGUGGGAGGAA 20 5143 BCL11A-4513 + GGUGGGAGGAAAGGGUG 17 5144 BCL11A-4514 + GGUGGGAGGAAAGGGUGGGG 20 5145 BCL11A-4515 + GGUUCCAGAUGGGAUGA 17 5146 BCL11A-4516 − GUAUUAUUUCUAAUUUAUUU 20 5147 BCL11A-4517 − GUCGAGGUAAAAGAGAUAAA 20 5148 BCL11A-4518 + GUGCGGGGAGGGGGAGGUGC 20 5149 BCL11A-4519 + GUGCGGGGCGGGGGGCUCCG 20 5150 BCL11A-4520 + GUGGCAGGGGUGGGAGGAAA 20 5151 BCL11A-4521 + GUGGCCGGGAGAGAAGAAAG 20 5152 BCL11A-4522 + GUGGGAGGAAAGGGUGG 17 5153 BCL11A-4523 + GUGGGCUGCGGGGCGGG 17 5154 BCL11A-4524 + GUGGGCUGCGGGGCGGGCGG 20 5155 BCL11A-4525 − GUGUGUGGGGGGGAGCA 17 5156

Table 10D provides exemplary targeting domains for knocking down expression of the BCL11A gene according to forth tier parameters. The targeting domains bind between 500 bp upstream and 500 bp downstream of transcription start site and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes eiCas9 molecule to cause a steric block at the target region, e.g., between 500 bp upstream and 500 bp downstream of transcription start site to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a S. pyogenes eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 10D 4th Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-4526 + AAAAAAAAAAAAAAAAAAAG 20 5157 BCL11A-4527 + AAAAAAAAAAAAAAAAAAGA 20 5158 BCL11A-4528 + AAAAAAAAAAAAAAAAG 17 5159 BCL11A-4529 + AAAAAAAAAAAAAAAGA 17 5160 BCL11A-4530 + AAAACAUGGGCAGGGCGAGC 20 5161 BCL11A-4531 − AAAACCCUCAUCCCAUC 17 5162 BCL11A-4532 − AAAACCUCCGAGAGUCG 17 5163 BCL11A-4533 − AAAAGCGAGGGGGAGAG 17 5164 BCL11A-4534 − AAAGCGAGGGGGAGAGA 17 5165 BCL11A-4535 + AAAGGGGUGGCAGGGGU 17 5166 BCL11A-4536 + AAAGGGGUGGCAGGGGUGGG 20 5167 BCL11A-4537 + AAAUAAUACAAAGAUGGCGC 20 5168 BCL11A-4538 − AACCCCAGCACUUAAGCAAA 20 5169 BCL11A-4539 + AACGUCAGGAGUCUGGA 17 5170 BCL11A-4540 + AAGAAAGGGGUGGCAGGGGU 20 5171 BCL11A-4541 + AAGAGACCAGGACAAGCCAA 20 5172 BCL11A-4542 + AAGCCAAUGGCCAGUGC 17 5173 BCL11A-4543 − AAGCGAGGGGGAGAGAG 17 5174 BCL11A-4544 + AAGUGCAUACACGGCAA 17 5175 BCL11A-4545 + AAUAAUACAAAGAUGGCGCA 20 5176 BCL11A-4546 + AAUACAAAGAUGGCGCA 17 5177 BCL11A-4547 + AAUGGACACACAUCAGGGGC 20 5178 BCL11A-4548 + AAUGGCCAGUGCGGGGA 17 5179 BCL11A-4549 + AAUGGUUCCAGAUGGGAUGA 20 5180 BCL11A-4550 + AAUUAAAUAAAAUUAAA 17 5181 BCL11A-4551 + AAUUAGAAAUAAUACAAAGA 20 5182 BCL11A-4552 − AAUUUAUUUUGGAUGUCAAA 20 5183 BCL11A-4553 + ACAAGCCAAUGGCCAGUGCG 20 5184 BCL11A-4554 + ACACACAAAACAUGGGC 17 5185 BCL11A-4555 + ACACCAAUGGACACACAUCA 20 5186 BCL11A-4556 + ACAUGGGCAGGGCGAGC 17 5187 BCL11A-4557 + ACCAAUGGACACACAUC 17 5188 BCL11A-4558 − ACCCCAGCACUUAAGCAAAC 20 5189 BCL11A-4559 − ACCCCUUUCUUCUCUCC 17 5190 BCL11A-4560 + ACGCCAGACGCGGCCCC 17 5191 BCL11A-4561 + ACGCCAGACGCGGCCCCCGG 20 5192 BCL11A-4562 + ACGCGGCCCCCGGGGGA 17 5193 BCL11A-4563 + ACGGCAAUGGUUCCAGA 17 5194 BCL11A-4564 − ACUAGAAGCAAAAGCGA 17 5195 BCL11A-4565 − ACUGAUGAAGAUAUUUUCUC 20 5196 BCL11A-4566 − ACUUGAACUUGCAGCUC 17 5197 BCL11A-4567 − ACUUGAACUUGCAGCUCAGG 20 5198 BCL11A-4568 − AGAAAAACCUCCGAGAGUCG 20 5199 BCL11A-4569 + AGAAGAAAGGGGUGGCA 17 5200 BCL11A-4570 + AGAAGGGGAGGAGGGAA 17 5201 BCL11A-4571 + AGACACACAAAACAUGGGCA 20 5202 BCL11A-4572 + AGACAUGGUGGGCUGCG 17 5203 BCL11A-4573 + AGACAUGGUGGGCUGCGGGG 20 5204 BCL11A-4574 + AGACCAGGACAAGCCAA 17 5205 BCL11A-4575 + AGACGCGGCCCCCGGGGGAG 20 5206 BCL11A-4576 + AGAGAAGAAAGGGGUGGCAG 20 5207 BCL11A-4577 + AGAGAAGGGGAGGAGGGAAG 20 5208 BCL11A-4578 + AGAGACACACAAAACAU 17 5209 BCL11A-4579 + AGAGAGAAGAGAGAUAG 17 5210 BCL11A-4580 + AGAGAGAGAAGAGAGAUAGA 20 5211 BCL11A-4581 + AGAGAGAGAGAUGAAAAAAA 20 5212 BCL11A-4582 − AGAGUCCGCGUGUGUGG 17 5213 BCL11A-4583 − AGCAAAAGCGAGGGGGAGAG 20 5214 BCL11A-4584 + AGCAGGAGAGAAGGGGAGGA 20 5215 BCL11A-4585 + AGCCAAUGGCCAGUGCG 17 5216 BCL11A-4586 + AGCCAAUGGCCAGUGCGGGG 20 5217 BCL11A-4587 − AGCCCCUGAUGUGUGUCCAU 20 5218 BCL11A-4588 + AGCGAGCGCCGCGGCGG 17 5219 BCL11A-4589 + AGCUGCAAGUUCAAGUG 17 5220 BCL11A-4590 − AGGACUAGAAGCAAAAGCGA 20 5221 BCL11A-4591 + AGGAGAGAAGGGGAGGA 17 5222 BCL11A-4592 + AGGGCGAGCAGGAGAGA 17 5223 BCL11A-4593 + AGGGGCGGGCCGAGGGG 17 5224 BCL11A-4594 + AGGGGCGGGCCGAGGGGAGG 20 5225 BCL11A-4595 + AGGGGGAGGUGCGGGGC 17 5226 BCL11A-4596 + AGGGGGAGGUGCGGGGCGGG 20 5227 BCL11A-4597 + AGGGGGCGCUGGGGCCG 17 5228 BCL11A-4598 + AGGGGUGGGAGGAAAGGGUG 20 5229 BCL11A-4599 − AGGUAAAAGAGAUAAAG 17 5230 BCL11A-4600 − AGUCCGCGUGUGUGGGG 17 5231 BCL11A-4601 − AGUCGAGGUAAAAGAGAUAA 20 5232 BCL11A-4602 + AGUGCGGGGAGGGGGAGGUG 20 5233 BCL11A-4603 + AGUGGCCGCAGCGAGCGCCG 20 5234 BCL11A-4604 + AUAAUUAUUAUUACUAUUAU 20 5235 BCL11A-4605 + AUCUCUUUUACCUCGACUCU 20 5236 BCL11A-4606 + AUGGCCAGUGCGGGGAG 17 5237 BCL11A-4607 + AUGGUGGGCUGCGGGGC 17 5238 BCL11A-4608 + AUGGUGGGCUGCGGGGCGGG 20 5239 BCL11A-4609 + AUUAUUAUUACUAUUAU 17 5240 BCL11A-4610 − AUUUUAGAGUCCGCGUGUGU 20 5241 BCL11A-4611 − CAAAAGCGAGGGGGAGAGAG 20 5242 BCL11A-4612 + CAAAAGUGCAUACACGGCAA 20 5243 BCL11A-4613 + CAAGCCAAUGGCCAGUG 17 5244 BCL11A-4614 + CAAUGGACACACAUCAG 17 5245 BCL11A-4615 + CAAUGGCCAGUGCGGGG 17 5246 BCL11A-4616 + CAAUGGCCAGUGCGGGGAGG 20 5247 BCL11A-4617 + CAAUGGUUCCAGAUGGGAUG 20 5248 BCL11A-4618 + CACACAAAACAUGGGCA 17 5249 BCL11A-4619 + CACACCAAUGGACACACAUC 20 5250 BCL11A-4620 + CACCAAUGGACACACAUCAG 20 5251 BCL11A-4621 − CACCGCCGCGGCGCUCGCUG 20 5252 BCL11A-4622 − CACUGGCCAUUGGCUUGUCC 20 5253 BCL11A-4623 − CACUUGAACUUGCAGCUCAG 20 5254 BCL11A-4624 + CAGACGCGGCCCCCGGGGGA 20 5255 BCL11A-4625 + CAGAGACACACAAAACA 17 5256 BCL11A-4626 − CAGGACUAGAAGCAAAAGCG 20 5257 BCL11A-4627 + CAGGAGAGAAGGGGAGG 17 5258 BCL11A-4628 + CAGGGAAGAUGAAUUGU 17 5259 BCL11A-4629 + CAGGGCGAGCAGGAGAGAAG 20 5260 BCL11A-4630 + CAGGGGUGGGAGGAAAGGGU 20 5261 BCL11A-4631 + CAUGGUGGGCUGCGGGG 17 5262 BCL11A-4632 + CCAAUGGACACACAUCA 17 5263 BCL11A-4633 + CCAAUGGCCAGUGCGGGGAG 20 5264 BCL11A-4634 + CCAGACGCGGCCCCCGG 17 5265 BCL11A-4635 + CCAGACGCGGCCCCCGGGGG 20 5266 BCL11A-4636 − CCAGCACUUAAGCAAAC 17 5267 BCL11A-4637 − CCAGCGCCCCCUCCCCU 17 5268 BCL11A-4638 + CCAGUGCGGGGAGGGGG 17 5269 BCL11A-4639 − CCCAGCACUUAAGCAAA 17 5270 BCL11A-4640 − CCCCCGGGGGCCGCGUC 17 5271 BCL11A-4641 − CCCCUCCCCGCACUGGCCAU 20 5272 BCL11A-4642 + CCCGGGGGAGGGGCGGGCCG 20 5273 BCL11A-4643 + CCCGUUUGCUUAAGUGC 17 5274 BCL11A-4644 − CCCUCGGCCCGCCCCUCCCC 20 5275 BCL11A-4645 − CCCUGAUGUGUGUCCAU 17 5276 BCL11A-4646 + CCGAGGGGAGGGGGCGC 17 5277 BCL11A-4647 − CCGCGUGUGUGGGGGGGAGC 20 5278 BCL11A-4648 + CCGGGGGAGGGGCGGGCCGA 20 5279 BCL11A-4649 + CCGUUUGCUUAAGUGCU 17 5280 BCL11A-4650 − CCUCCCCCGGGGGCCGCGUC 20 5281 BCL11A-4651 − CCUCCCCCUCCCCGCAC 17 5282 BCL11A-4652 − CCUCGGCCCGCCCCUCCCCC 20 5283 BCL11A-4653 + CCUGCUCCCCCCCACACACG 20 5284 BCL11A-4654 + CGAGACAUGGUGGGCUG 17 5285 BCL11A-4655 + CGAGCGCCGCGGCGGUGGCG 20 5286 BCL11A-4656 + CGAGGGGAGGGGGCGCU 17 5287 BCL11A-4657 − CGAGGUAAAAGAGAUAA 17 5288 BCL11A-4658 − CGAGGUAAAAGAGAUAAAGG 20 5289 BCL11A-4659 − CGCACUUGAACUUGCAGCUC 20 5290 BCL11A-4660 + CGCAGCGAGCGCCGCGG 17 5291 BCL11A-4661 + CGCAGCGAGCGCCGCGGCGG 20 5292 BCL11A-4662 + CGCCAGACGCGGCCCCC 17 5293 BCL11A-4663 − CGCCGCGGCGCUCGCUG 17 5294 BCL11A-4664 + CGCCGCGGCGGUGGCGUGGC 20 5295 BCL11A-4665 + CGCGGCCCCCGGGGGAG 17 5296 BCL11A-4666 + CGCGGCCCCCGGGGGAGGGG 20 5297 BCL11A-4667 + CGCGGCGGUGGCGUGGC 17 5298 BCL11A-4668 − CGCGUGUGUGGGGGGGAGCA 20 5299 BCL11A-4669 + CGGCAAUGGUUCCAGAU 17 5300 BCL11A-4670 − CGGCCACGCCACCGCCG 17 5301 BCL11A-4671 − CGGCCCGCCCCUCCCCC 17 5302 BCL11A-4672 + CGGCGAGACAUGGUGGGCUG 20 5303 BCL11A-4673 + CGGCGGCGGCGGGCGGACGA 20 5304 BCL11A-4674 + CGGCGGCGGGCGGACGA 17 5305 BCL11A-4675 + CGGGGAGGGGGAGGUGC 17 5306 BCL11A-4676 + CGGGGCGGGGGGCUCCG 17 5307 BCL11A-4677 + CGGGGGAGGGGCGGGCCGAG 20 5308 BCL11A-4678 + CGUGGCCGGGAGAGAAGAAA 20 5309 BCL11A-4679 − CGUGUGUGGGGGGGAGC 17 5310 BCL11A-4680 + CGUUUGCUUAAGUGCUG 17 5311 BCL11A-4681 − CUAGAAGCAAAAGCGAG 17 5312 BCL11A-4682 − CUCCCCGCACUGGCCAU 17 5313 BCL11A-4683 − CUCGGCCCGCCCCUCCCCCG 20 5314 BCL11A-4684 + CUGAGCUGCAAGUUCAAGUG 20 5315 BCL11A-4685 + CUGCGAACUUGAACGUC 17 5316 BCL11A-4686 + CUGGACAUGAAAAAGAGACC 20 5317 BCL11A-4687 + CUGUCUCAAAAGUGCAUACA 20 5318 BCL11A-4688 + CUUGAACGUCAGGAGUC 17 5319 BCL11A-4689 − CUUGAACUUGCAGCUCA 17 5320 BCL11A-4690 − CUUGAACUUGCAGCUCAGGG 20 5321 BCL11A-4691 + CUUGCGGCGAGACAUGG 17 5322 BCL11A-4692 + GUUCACAUCGGGAGAGC 17 5323 BCL11A-4693 + UAAUACAAAGAUGGCGC 17 5324 BCL11A-4694 + UAAUUAUUAUUACUAUUAUU 20 5325 BCL11A-4695 + UACACGGCAAUGGUUCCAGA 20 5326 BCL11A-4696 + UAGAAAUAAUACAAAGA 17 5327 BCL11A-4697 − UAGAAGCAAAAGCGAGG 17 5328 BCL11A-4698 − UAGAGUCCGCGUGUGUG 17 5329 BCL11A-4699 − UAGAGUCCGCGUGUGUGGGG 20 5330 BCL11A-4700 − UCCCGGCCACGCCACCGCCG 20 5331 BCL11A-4701 + UCCCGUUUGCUUAAGUGCUG 20 5332 BCL11A-4702 + UCCCUGCGAACUUGAACGUC 20 5333 BCL11A-4703 − UCGAGGUAAAAGAGAUAAAG 20 5334 BCL11A-4704 − UCGGCCCGCCCCUCCCC 17 5335 BCL11A-4705 − UCGGCCCGCCCCUCCCCCGG 20 5336 BCL11A-4706 + UCUCAAAAGUGCAUACA 17 5337 BCL11A-4707 − UCUCCUUCUUUCUAACC 17 5338 BCL11A-4708 + UCUUUUACCUCGACUCU 17 5339 BCL11A-4709 − UGAACUUGCAGCUCAGG 17 5340 BCL11A-4710 − UGCGGCCACUGGUGAGCCCG 20 5341 BCL11A-4711 + UGCGGGGAGGGGGAGGUGCG 20 5342 BCL11A-4712 + UGCGGGGCGGGCGGCGG 17 5343 BCL11A-4713 + UGCGGGGCGGGCGGCGGCGG 20 5344 BCL11A-4714 − UGCUUAAAAAAAAGCCAUGA 20 5345 BCL11A-4715 + UGGCCAGUGCGGGGAGG 17 5346 BCL11A-4716 + UGGCCAGUGCGGGGAGGGGG 20 5347 BCL11A-4717 − UGGCCAUUGGCUUGUCC 17 5348 BCL11A-4718 + UGGCCGGGAGAGAAGAA 17 5349 BCL11A-4719 + UGGGAGGAAAGGGUGGG 17 5350 BCL11A-4720 + UGGGGCCGCGGGCUCACCAG 20 5351 BCL11A-4721 + UGGUUCCAGAUGGGAUG 17 5352 BCL11A-4722 − UUAAAAAAAAGCCAUGA 17 5353 BCL11A-4723 − UUAGAGUCCGCGUGUGUGGG 20 5354 BCL11A-4724 + UUAUUAUUACUAUUAUU 17 5355 BCL11A-4725 − UUAUUUCUAAUUUAUUU 17 5356 BCL11A-4726 − UUAUUUUGGAUGUCAAA 17 5357 BCL11A-4727 + UUCACAUCGGGAGAGCC 17 5358 BCL11A-4728 + UUCCCGUUUGCUUAAGUGCU 20 5359 BCL11A-4729 + UUGAACGUCAGGAGUCUGGA 20 5360 BCL11A-4730 − UUGAACUUGCAGCUCAG 17 5361 BCL11A-4731 + UUGCUUGCGGCGAGACAUGG 20 5362 BCL11A-4732 + UUGUGGGAGAGCCGUCA 17 5363 BCL11A-4733 − UUUUAGAGUCCGCGUGUGUG 20 5364

Table 11A provides exemplary targeting domains for knocking down expression of the BCL11A gene according to first tier parameters. The targeting domains bind between 500 bp upstream and 500 bp downstream of transcription start site, good orthogonality, starts with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule to cause a steric block at the target region, e.g., between 500 bp upstream and 500 bp downstream of transcription start site to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a S. aureus eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 11A 1st Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-4734 + GACGACGGCUCGGUUCACAU 20 6365 BCL11A-4735 + GACGGCUCGGUUCACAU 17 6366 BCL11A-4736 + GACGGCUCGGUUCACAUCGG 20 6367 BCL11A-4737 + GACGUGACGUCCCUGCGAAC 20 6368 BCL11A-4738 + GCGGACGUGACGUCCCU 17 6369 BCL11A-4739 + GGACGACGGCUCGGUUCACA 20 6370 BCL11A-4740 − GGACGUCACGUCCGCAC 17 6371 BCL11A-4741 + GGCUCGGUUCACAUCGG 17 6372 BCL11A-4742 − GGCUCUCCCGAUGUGAA 17 6373 BCL11A-4743 + GGUUCACAUCGGGAGAG 17 6374 BCL11A-4744 + GUCCCUGCGAACUUGAACGU 20 6375 BCL11A-4745 + GUGACGUCCCUGCGAAC 17 6376

Table 11B provides exemplary targeting domains for knocking down expression of the BCL11A gene according to second tier parameters. The targeting domains bind between 500 bp upstream and 500 bp downstream of transcription start site, good orthogonality and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule to cause a steric block at the target region, e.g., between 500 bp upstream and 500 bp downstream of transcription start site to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a S. aureus eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 11B 2nd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-4746 + ACGACGGCUCGGUUCACAUC 20 6377 BCL11A-4747 − ACGAGAGCGCGCAGGAC 17 6378 BCL11A-4748 + ACGGCUCGGUUCACAUC 17 6379 BCL11A-4749 + AGUGCGGACGUGACGUCCCU 20 6380 BCL11A-4750 − AUCACGAGAGCGCGCAGGAC 20 6381 BCL11A-4751 − CAGGGACGUCACGUCCGCAC 20 6382 BCL11A-4752 + CAUCGGGAGAGCCGGGU 17 6383 BCL11A-4753 − CCCGGCUCUCCCGAUGUGAA 20 6384 BCL11A-4754 + CCUGCGAACUUGAACGU 17 6385 BCL11A-4755 + CGACGGCUCGGUUCACA 17 6386 BCL11A-4756 + CUCGGUUCACAUCGGGAGAG 20 6387 BCL11A-4757 + CUGCGAACUUGAACGUC 17 6388 BCL11A-4758 + UCACAUCGGGAGAGCCGGGU 20 6389 BCL11A-4759 + UCCCUGCGAACUUGAACGUC 20 6390

Table 11C provides exemplary targeting domains for knocking down expression of the BCL11A gene according to third tier parameters. The targeting domains bind between 500 bp upstream and 500 bp downstream of transcription start site and start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule to cause a steric block at the target region, e.g., between 500 bp upstream and 500 bp downstream of transcription start site to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a S. aureus eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 11C 3rd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-4760 − GAAAAAACCCUCAUCCCAUC 20 6391 BCL11A-4761 + GAAAGAAGGAGACUCCA 17 6392 BCL11A-4762 + GAAAGGGGUGGCAGGGG 17 6393 BCL11A-4763 + GAAAGGGGUGGCAGGGGUGG 20 6394 BCL11A-4764 + GAAAUAAUACAAAGAUGGCG 20 6395 BCL11A-4765 + GAACGUCAGGAGUCUGG 17 6396 BCL11A-4766 + GAAGAAAGGGGUGGCAGGGG 20 6397 BCL11A-4767 + GAAGAGAGAUAGAGGGA 17 6398 BCL11A-4768 − GAAGCAAAAGCGAGGGG 17 6399 BCL11A-4769 + GAAGGGGAGGAGGGAAG 17 6400 BCL11A-4770 + GACAAGCCAAUGGCCAGUGC 20 6401 BCL11A-4771 + GACACACAAAACAUGGG 17 6402 BCL11A-4772 + GACGCCAGACGCGGCCC 17 6403 BCL11A-4773 + GACGCCAGACGCGGCCCCCG 20 6404 BCL11A-4774 + GACGCGGCCCCCGGGGG 17 6405 BCL11A-4775 − GACUAGAAGCAAAAGCG 17 6406 BCL11A-4776 − GACUAGAAGCAAAAGCGAGG 20 6407 BCL11A-4777 + GACUCUCGGAGGUUUUUCUC 20 6408 BCL11A-4778 + GAGAAGAAAGGGGUGGC 17 6409 BCL11A-4779 + GAGAAGAGAGAUAGAGG 17 6410 BCL11A-4780 + GAGAAGGGGAGGAGGGA 17 6411 BCL11A-4781 + GAGACAUGGUGGGCUGCGGG 20 6412 BCL11A-4782 + GAGAGAAGAGAGAUAGA 17 6413 BCL11A-4783 + GAGAGAAGGGGAGGAGGGAA 20 6414 BCL11A-4784 + GAGAGAGAAGAGAGAUA 17 6415 BCL11A-4785 + GAGAGAGAGAAGAGAGA 17 6416 BCL11A-4786 + GAGAGAGAGAAGAGAGAUAG 20 6417 BCL11A-4787 + GAGAGAGAGAGAGAGAG 17 6418 BCL11A-4788 + GAGAGAUAGAGGGAGAGAGA 20 6419 BCL11A-4789 + GAGAUAGAGGGAGAGAGAGA 20 6420 BCL11A-4790 + GAGCAGGAGAGAAGGGG 17 6421 BCL11A-4791 + GAGCAGGAGAGAAGGGGAGG 20 6422 BCL11A-4792 + GAGCCGGGUUAGAAAGA 17 6423 BCL11A-4793 + GAGCUGCAAGUUCAAGU 17 6424 BCL11A-4794 + GAGGGAGAGAGAGAGAA 17 6425 BCL11A-4795 + GAGGGGCGGGCCGAGGG 17 6426 BCL11A-4796 + GAGGGGGAGGUGCGGGG 17 6427 BCL11A-4797 + GAGGGGGCGCUGGGGCC 17 6428 BCL11A-4798 − GAGGUAAAAGAGAUAAA 17 6429 BCL11A-4799 − GAGUCCGCGUGUGUGGG 17 6430 BCL11A-4800 − GAGUCGAGGUAAAAGAGAUA 20 6431 BCL11A-4801 + GAUAGAGGGAGAGAGAGAGA 20 6432 BCL11A-4802 − GAUGAAGAUAUUUUCUC 17 6433 BCL11A-4803 − GAUGUCAAAAGGCACUG 17 6434 BCL11A-4804 − GAUGUGUGUCCAUUGGU 17 6435 BCL11A-4805 + GCAAUGGUUCCAGAUGGGAU 20 6436 BCL11A-4806 − GCACUUGAACUUGCAGCUCA 20 6437 BCL11A-4807 − GCAGGACUAGAAGCAAAAGC 20 6438 BCL11A-4808 + GCAGGAGAGAAGGGGAG 17 6439 BCL11A-4809 + GCAGGGAAGAUGAAUUG 17 6440 BCL11A-4810 + GCAGGGAAGAUGAAUUGUGG 20 6441 BCL11A-4811 + GCAGGGCGAGCAGGAGAGAA 20 6442 BCL11A-4812 + GCAGGGGUGGGAGGAAAGGG 20 6443 BCL11A-4813 − GCAUUUUUAAAUUUUUC 17 6444 BCL11A-4814 + GCCAAUGGCCAGUGCGGGGA 20 6445 BCL11A-4815 + GCCAGACGCGGCCCCCG 17 6446 BCL11A-4816 + GCCAGACGCGGCCCCCGGGG 20 6447 BCL11A-4817 + GCCCCCGGGGGAGGGGCGGG 20 6448 BCL11A-4818 + GCCGAGGGGAGGGGGCG 17 6449 BCL11A-4819 + GCCGCGGCGGUGGCGUGGCC 20 6450 BCL11A-4820 − GCCGCGUCUGGCGUCCG 17 6451 BCL11A-4821 + GCGAGACAUGGUGGGCU 17 6452 BCL11A-4822 − GCGCAGGACUAGAAGCAAAA 20 6453 BCL11A-4823 + GCGCAGGGAAGAUGAAUUGU 20 6454 BCL11A-4824 + GCGCCGCGGCGGUGGCGUGG 20 6455 BCL11A-4825 + GCGGACGCCAGACGCGGCCC 20 6456 BCL11A-4826 + GCGGCGAGACAUGGUGGGCU 20 6457 BCL11A-4827 + GCGGCGGUGGCGUGGCC 17 6458 BCL11A-4828 + GCGGGGAGGGGGAGGUG 17 6459 BCL11A-4829 + GCGGGGCGGGGGGCUCC 17 6460 BCL11A-4830 + GCGUGGCCGGGAGAGAAGAA 20 6461 BCL11A-4831 − GCGUGUGUGGGGGGGAG 17 6462 BCL11A-4832 + GCUCACCAGUGGCCGCA 17 6463 BCL11A-4833 − GCUCGCUGCGGCCACUG 17 6464 BCL11A-4834 + GCUGGACAUGAAAAAGAGAC 20 6465 BCL11A-4835 + GCUUGCGGCGAGACAUG 17 6466 BCL11A-4836 − GGAAAAAACCCUCAUCCCAU 20 6467 BCL11A-4837 + GGAAGGGGAAGCUCACACCA 20 6468 BCL11A-4838 + GGACAAGCCAAUGGCCAGUG 20 6469 BCL11A-4839 + GGACAUGAAAAAGAGAC 17 6470 BCL11A-4840 + GGACGCCAGACGCGGCCCCC 20 6471 BCL11A-4841 − GGACUAGAAGCAAAAGC 17 6472 BCL11A-4842 − GGACUAGAAGCAAAAGCGAG 20 6473 BCL11A-4843 + GGAGAGAAGAAAGGGGUGGC 20 6474 BCL11A-4844 + GGAGAGAAGGGGAGGAGGGA 20 6475 BCL11A-4845 + GGAGAGAGAGAGAAGAGAGA 20 6476 BCL11A-4846 + GGAGAGCCGGGUUAGAAAGA 20 6477 BCL11A-4847 + GGAGGGGCGGGCCGAGGGGA 20 6478 BCL11A-4848 + GGAGGGGGAGGUGCGGG 17 6479 BCL11A-4849 + GGAGGGGGAGGUGCGGGGCG 20 6480 BCL11A-4850 + GGCAGGGCGAGCAGGAGAGA 20 6481 BCL11A-4851 + GGCAGGGGUGGGAGGAAAGG 20 6482 BCL11A-4852 − GGCCGCGUCUGGCGUCC 17 6483 BCL11A-4853 + GGCGAGCAGGAGAGAAG 17 6484 BCL11A-4854 + GGCGAGCAGGAGAGAAGGGG 20 6485 BCL11A-4855 + GGCGCAGGGAAGAUGAAUUG 20 6486 BCL11A-4856 − GGCGCUCGCUGCGGCCACUG 20 6487 BCL11A-4857 + GGCGGCGGCGGCGGCGG 17 6488 BCL11A-4858 + GGCGGCGGCGGCGGCGGCGG 20 6489 BCL11A-4859 + GGCGGUGGCGUGGCCGG 17 6490 BCL11A-4860 + GGCGUGGCCGGGAGAGAAGA 20 6491 BCL11A-4861 + GGGAAGAUGAAUUGUGG 17 6492 BCL11A-4862 + GGGAGAGAAGAAAGGGGUGG 20 6493 BCL11A-4863 + GGGAGAGCCGGGUUAGA 17 6494 BCL11A-4864 + GGGAGAGCCGGGUUAGAAAG 20 6495 BCL11A-4865 + GGGAGGAAAGGGUGGGG 17 6496 BCL11A-4866 + GGGAGGGGCGGGCCGAG 17 6497 BCL11A-4867 + GGGAGGGGCGGGCCGAGGGG 20 6498 BCL11A-4868 + GGGAGGGGGAGGUGCGGGGC 20 6499 BCL11A-4869 + GGGCAGGGCGAGCAGGA 17 6500 BCL11A-4870 + GGGCAGGGCGAGCAGGAGAG 20 6501 BCL11A-4871 + GGGCCGAGGGGAGGGGGCGC 20 6502 BCL11A-4872 + GGGCGAGCAGGAGAGAA 17 6503 BCL11A-4873 + GGGCGAGCAGGAGAGAAGGG 20 6504 BCL11A-4874 + GGGGAGGGGCGGGCCGA 17 6505 BCL11A-4875 + GGGGAGGGGCGGGCCGAGGG 20 6506 BCL11A-4876 + GGGGAGGGGGAGGUGCGGGG 20 6507 BCL11A-4877 + GGGGAGGGGGCGCUGGGGCC 20 6508 BCL11A-4878 − GGGGCCGCGUCUGGCGUCCG 20 6509 BCL11A-4879 + GGGGCGGGCCGAGGGGA 17 6510 BCL11A-4880 + GGGGGAGGGGCGGGCCG 17 6511 BCL11A-4881 + GGGGGAGGUGCGGGGCG 17 6512 BCL11A-4882 − GGGGGCCGCGUCUGGCGUCC 20 6513 BCL11A-4883 + GGGGUGGCAGGGGUGGG 17 6514 BCL11A-4884 + GGGGUGGGAGGAAAGGG 17 6515 BCL11A-4885 + GGGGUGGGAGGAAAGGGUGG 20 6516 BCL11A-4886 + GGGUGGCAGGGGUGGGAGGA 20 6517 BCL11A-4887 + GGGUGGGAGGAAAGGGU 17 6518 BCL11A-4888 + GGGUGGGAGGAAAGGGUGGG 20 6519 BCL11A-4889 − GGUAAAAGAGAUAAAGG 17 6520 BCL11A-4890 + GGUGCGGGGCGGGGGGCUCC 20 6521 BCL11A-4891 + GGUGGGAGGAAAGGGUG 17 6522 BCL11A-4892 + GGUGGGAGGAAAGGGUGGGG 20 6523 BCL11A-4893 + GGUUAGAAAGAAGGAGACUC 20 6524 BCL11A-4894 + GGUUUGCCUUGCUUGCG 17 6525 BCL11A-4895 − GUCGAGGUAAAAGAGAUAAA 20 6526 BCL11A-4896 + GUGGCCGGGAGAGAAGA 17 6527 BCL11A-4897 + GUGGGAGGAAAGGGUGG 17 6528

Table 11D provides exemplary targeting domains for knocking down expression of the BCL11A gene according to forth tier parameters. The targeting domains bind between 500 bp upstream and 500 bp downstream of transcription start site and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule to cause a steric block at the target region, e.g., between 500 bp upstream and 500 bp downstream of transcription start site to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a S. aureus eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 11D 4th Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-4898 + AAAAAAAAAAAAAAAAA 17 6529 BCL11A-4899 + AAAAAAAAAAAAAAAAAAAA 20 6530 BCL11A-4900 + AAAAAAAAAAAAAAAAAAAG 20 6531 BCL11A-4901 + AAAAAAAAAAAAAAAAAAGA 20 6532 BCL11A-4902 + AAAAAAAAAAAAAAAAG 17 6533 BCL11A-4903 + AAAAAAAAAAAAAAAAGAGG 20 6534 BCL11A-4904 + AAAAAAAAAAAAAAAGA 17 6535 BCL11A-4905 + AAAAAAAAAAAAAAGAGGGA 20 6536 BCL11A-4906 + AAAAAAAAAAAAAGAGG 17 6537 BCL11A-4907 + AAAAAAAAAAAAGAGGGAGA 20 6538 BCL11A-4908 + AAAAAAAAAAAGAGGGA 17 6539 BCL11A-4909 + AAAAAAAAAAGAGGGAGAGA 20 6540 BCL11A-4910 + AAAAAAAAAGAGGGAGA 17 6541 BCL11A-4911 + AAAAAAAAGAGGGAGAGAGA 20 6542 BCL11A-4912 + AAAAAAAGAGGGAGAGA 17 6543 BCL11A-4913 + AAAAAAUGGCAAAAGCCCCC 20 6544 BCL11A-4914 - AAAAACCCUCAUCCCAU 17 6545 BCL11A-4915 + AAAAAGAGGGAGAGAGA 17 6546 BCL11A-4916 + AAAAAGAGGGAGAGAGAGAG 20 6547 BCL11A-4917 + AAAACAUGGGCAGGGCGAGC 20 6548 BCL11A-4918 - AAAACCCUCAUCCCAUC 17 6549 BCL11A-4919 - AAAAGCGAGGGGGAGAG 17 6550 BCL11A-4920 - AAACCCCAGCACUUAAGCAA 20 6551 BCL11A-4921 + AAAGAGGGAGAGAGAGAGAA 20 6552 BCL11A-4922 + AAAGGGGUGGCAGGGGU 17 6553 BCL11A-4923 + AAAGGGGUGGCAGGGGUGGG 20 6554 BCL11A-4924 + AAAUAAUACAAAGAUGGCGC 20 6555 BCL11A-4925 + AAAUGGCAAAAGCCCCC 17 6556 BCL11A-4926 + AACAUGGGCAGGGCGAG 17 6557 BCL11A-4927 + AACAUGGGCAGGGCGAGCAG 20 6558 BCL11A-4928 - AACCCCAGCACUUAAGCAAA 20 6559 BCL11A-4929 - AACCCGGCUCUCCCGAU 17 6560 BCL11A-4930 + AAGAAAGGGGUGGCAGGGGU 20 6561 BCL11A-4931 + AAGAGAGAUAGAGGGAGAGA 20 6562 BCL11A-4932 + AAGAGGGAGAGAGAGAG 17 6563 BCL11A-4933 + AAGAUGGCGCAGGGAAG 17 6564 BCL11A-4934 - AAGCAAAAGCGAGGGGGAGA 20 6565 BCL11A-4935 + AAGCCAAUGGCCAGUGC 17 6566 BCL11A-4936 + AAGCCAAUGGCCAGUGCGGG 20 6567 BCL11A-4937 - AAUAAUAAUUAUUAAUAAUC 20 6568 BCL11A-4938 + AAUAAUACAAAGAUGGCGCA 20 6569 BCL11A-4939 - AAUAAUUAUUAAUAAUC 17 6570 BCL11A-4940 + AAUAAUUAUUAUUACUAUUA 20 6571 BCL11A-4941 + AAUACAAAGAUGGCGCA 17 6572 BCL11A-4942 + AAUGGCCAGUGCGGGGA 17 6573 BCL11A-4943 + AAUUAUUAUUACUAUUA 17 6574 BCL11A-4944 + AAUUCCCGUUUGCUUAAGUG 20 6575 BCL11A-4945 + ACAAAGAUGGCGCAGGGAAG 20 6576 BCL11A-4946 + ACAAGCCAAUGGCCAGU 17 6577 BCL11A-4947 + ACAAGCCAAUGGCCAGUGCG 20 6578 BCL11A-4948 + ACACACAAAACAUGGGCAGG 20 6579 BCL11A-4949 + ACACACAUCAGGGGCUGGAC 20 6580 BCL11A-4950 + ACAGAGACACACAAAAC 17 6581 BCL11A-4951 + ACAUGGGCAGGGCGAGC 17 6582 BCL11A-4952 + ACAUGGUGGGCUGCGGG 17 6583 BCL11A-4953 + ACCAAUGGACACACAUC 17 6584 BCL11A-4954 - ACCCCAGCACUUAAGCAAAC 20 6585 BCL11A-4955 - ACCUCCGAGAGUCGAGGUAA 20 6586 BCL11A-4956 - ACGAGAAAAACCUCCGAGAG 20 6587 BCL11A-4957 + ACGCCAGACGCGGCCCC 17 6588 BCL11A-4958 + ACGCCAGACGCGGCCCCCGG 20 6589 BCL11A-4959 + ACGCGGCCCCCGGGGGAGGG 20 6590 BCL11A-4960 + ACGGCAAUGGUUCCAGA 17 6591 BCL11A-4961 + ACGUCAGGAGUCUGGAUGGA 20 6592 BCL11A-4962 - ACUAGAAGCAAAAGCGA 17 6593 BCL11A-4963 + ACUAUUAUUGGGUUACUUAC 20 6594 BCL11A-4964 - ACUCCUGACGUUCAAGUUCG 20 6595 BCL11A-4965 - ACUGAUGAAGAUAUUUUCUC 20 6596 BCL11A-4966 + ACUUGAACGUCAGGAGU 17 6597 BCL11A-4967 - ACUUGAACUUGCAGCUC 17 6598 BCL11A-4968 - AGAAAAACCUCCGAGAG 17 6599 BCL11A-4969 + AGAAAGGGGUGGCAGGG 17 6600 BCL11A-4970 + AGAAGAAAGGGGUGGCAGGG 20 6601 BCL11A-4971 + AGAAGAGAGAUAGAGGGAGA 20 6602 BCL11A-4972 - AGAAGCAAAAGCGAGGGGGA 20 6603 BCL11A-4973 + AGAAGGGGAGGAGGGAA 17 6604 BCL11A-4974 + AGACGCGGCCCCCGGGG 17 6605 BCL11A-4975 + AGAGAAGAAAGGGGUGG 17 6606 BCL11A-4976 + AGAGAAGAGAGAUAGAGGGA 20 6607 BCL11A-4977 + AGAGAAGGGGAGGAGGG 17 6608 BCL11A-4978 + AGAGAAGGGGAGGAGGGAAG 20 6609 BCL11A-4979 + AGAGACACACAAAACAUGGG 20 6610 BCL11A-4980 + AGAGAGAAGAGAGAUAG 17 6611 BCL11A-4981 + AGAGAGAAGAGAGAUAGAGG 20 6612 BCL11A-4982 + AGAGAGAGAAGAGAGAUAGA 20 6613 BCL11A-4983 + AGAGAGAGAGAAGAGAGAUA 20 6614 BCL11A-4984 + AGAGAGAUAGAGGGAGA 17 6615 BCL11A-4985 + AGAGAUAGAGGGAGAGA 17 6616 BCL11A-4986 + AGAGCCGGGUUAGAAAG 17 6617 BCL11A-4987 + AGAGGGAGAGAGAGAGA 17 6618 BCL11A-4988 - AGAGUCCGCGUGUGUGG 17 6619 BCL11A-4989 + AGAUAGAGGGAGAGAGA 17 6620 BCL11A-4990 - AGCAAAAGCGAGGGGGA 17 6621 BCL11A-4991 - AGCAAAAGCGAGGGGGAGAG 20 6622 BCL11A-4992 + AGCAGGAGAGAAGGGGAGGA 20 6623 BCL11A-4993 + AGCCAAUGGCCAGUGCG 17 6624 BCL11A-4994 + AGCCAAUGGCCAGUGCGGGG 20 6625 BCL11A-4995 + AGGACAAGCCAAUGGCCAGU 20 6626 BCL11A-4996 - AGGACUAGAAGCAAAAGCGA 20 6627 BCL11A-4997 + AGGAGAGAAGGGGAGGA 17 6628 BCL11A-4998 + AGGAGAGAAGGGGAGGAGGG 20 6629 BCL11A-4999 + AGGGAGAGAGAGAGAGAGAG 20 6630 BCL11A-5000 + AGGGCGAGCAGGAGAGA 17 6631 BCL11A-5001 + AGGGGAAGCUCACACCA 17 6632 BCL11A-5002 + AGGGGCGGGCCGAGGGG 17 6633 BCL11A-5003 + AGGGGCUGGACAUGAAA 17 6634 BCL11A-5004 + AGGGGGAGGUGCGGGGC 17 6635 BCL11A-5005 + AGGGGUGGCAGGGGUGG 17 6636 BCL11A-5006 + AGGGGUGGGAGGAAAGG 17 6637 BCL11A-5007 + AGGGGUGGGAGGAAAGGGUG 20 6638 BCL11A-5008 - AGGUAAAAGAGAUAAAG 17 6639 BCL11A-5009 - AGUCCGCGUGUGUGGGG 17 6640 BCL11A-5010 - AGUCGAGGUAAAAGAGAUAA 20 6641 BCL11A-5011 + AGUGCGGGGAGGGGGAGGUG 20 6642 BCL11A-5012 + AUAAUACAAAGAUGGCG 17 6643 BCL11A-5013 - AUAAUCACGAGAGCGCG 17 6644 BCL11A-5014 + AUACACGGCAAUGGUUCCAG 20 6645 BCL11A-5015 + AUAGAGGGAGAGAGAGA 17 6646 BCL11A-5016 + AUCAGGGGCUGGACAUGAAA 20 6647 BCL11A-5017 + AUCGGGAGAGCCGGGUUAGA 20 6648 BCL11A-5018 + AUCUCUUUUACCUCGACUCU 20 6649 BCL11A-5019 + AUGGCCAGUGCGGGGAG 17 6650 BCL11A-5020 + AUGGGCAGGGCGAGCAG 17 6651 BCL11A-5021 + AUGGUUCCAGAUGGGAU 17 6652 BCL11A-5022 + AUUAUUGGGUUACUUAC 17 6653 BCL11A-5023 - AUUAUUUCUAAUUUAUU 17 6654 BCL11A-5024 + AUUCCCGUUUGCUUAAGUGC 20 6655 BCL11A-5025 - AUUUUAGAGUCCGCGUGUGU 20 6656 BCL11A-5026 - AUUUUUAAAUUUUUCAC 17 6657 BCL11A-5027 - AUUUUUCACGAGAAAAACCU 20 6658 BCL11A-5028 + CAAAACAUGGGCAGGGCGAG 20 6659 BCL11A-5029 - CAAAAGCGAGGGGGAGA 17 6660 BCL11A-5030 + CAAGCCAAUGGCCAGUG 17 6661 BCL11A-5031 + CAAUGGACACACAUCAGGGG 20 6662 BCL11A-5032 + CAAUGGCCAGUGCGGGG 17 6663 BCL11A-5033 + CAAUGGCCAGUGCGGGGAGG 20 6664 BCL11A-5034 + CAAUGGUUCCAGAUGGG 17 6665 BCL11A-5035 + CACAAAACAUGGGCAGG 17 6666 BCL11A-5036 + CACACCAAUGGACACACAUC 20 6667 BCL11A-5037 + CACACGCGGACUCUAAA 17 6668 BCL11A-5038 + CACAUCAGGGGCUGGAC 17 6669 BCL11A-5039 + CACCAAUGGACACACAU 17 6670 BCL11A-5040 + CACGGCAAUGGUUCCAG 17 6671 BCL11A-5041 - CACUGAUGAAGAUAUUUUCU 20 6672 BCL11A-5042 - CACUUGAACUUGCAGCU 17 6673 BCL11A-5043 - CACUUGAACUUGCAGCUCAG 20 6674 BCL11A-5044 - CAGGACUAGAAGCAAAA 17 6675 BCL11A-5045 - CAGGACUAGAAGCAAAAGCG 20 6676 BCL11A-5046 + CAGGAGAGAAGGGGAGG 17 6677 BCL11A-5047 + CAGGGAAGAUGAAUUGU 17 6678 BCL11A-5048 + CAGGGCGAGCAGGAGAG 17 6679 BCL11A-5049 + CAGGGCGAGCAGGAGAGAAG 20 6680 BCL11A-5050 + CAGGGGUGGGAGGAAAGGGU 20 6681 BCL11A-5051 + CAGUGCGGGGAGGGGGAGGU 20 6682 BCL11A-5052 - CAUGCAUUUUUAAAUUUUUC 20 6683 BCL11A-5053 + CAUGGGCAGGGCGAGCAGGA 20 6684 BCL11A-5054 - CAUUUUAGAGUCCGCGUGUG 20 6685 BCL11A-5055 + CCAAUGGCCAGUGCGGG 17 6686 BCL11A-5056 + CCAAUGGCCAGUGCGGGGAG 20 6687 BCL11A-5057 + CCACACACGCGGACUCUAAA 20 6688 BCL11A-5058 + CCAGACGCGGCCCCCGG 17 6689 BCL11A-5059 + CCAGACGCGGCCCCCGGGGG 20 6690 BCL11A-5060 - CCAGCACUUAAGCAAAC 17 6691 BCL11A-5061 - CCAUUGCCGUGUAUGCACUU 20 6692 BCL11A-5062 - CCCAGCACUUAAGCAAA 17 6693 BCL11A-5063 - CCCCAGCACUUAAGCAA 17 6694 BCL11A-5064 + CCCCGGGGGAGGGGCGGGCC 20 6695 BCL11A-5065 - CCCCUCGGCCCGCCCCUCCC 20 6696 BCL11A-5066 + CCCGGGGGAGGGGCGGG 17 6697 BCL11A-5067 + CCCGGGGGAGGGGCGGGCCG 20 6698 BCL11A-5068 + CCCGUUUGCUUAAGUGC 17 6699 BCL11A-5069 - CCCUCGGCCCGCCCCUCCCC 20 6700 BCL11A-5070 + CCCUGCUCCCCCCCACACAC 20 6701 BCL11A-5071 + CCGAGGGGAGGGGGCGC 17 6702 BCL11A-5072 - CCGCACUUGAACUUGCAGCU 20 6703 BCL11A-5073 + CCGCGGCGGUGGCGUGG 17 6704 BCL11A-5074 + CCGGGGGAGGGGCGGGCCGA 20 6705 BCL11A-5075 - CCUCGGCCCGCCCCUCCCCC 20 6706 BCL11A-5076 - CCUGACGUUCAAGUUCG 17 6707 BCL11A-5077 + CCUGAGCUGCAAGUUCAAGU 20 6708 BCL11A-5078 - CCUGAUGUGUGUCCAUUGGU 20 6709 BCL11A-5079 + CGAACUUGAACGUCAGGAGU 20 6710 BCL11A-5080 + CGAGACAUGGUGGGCUG 17 6711 BCL11A-5081 + CGAGCAGGAGAGAAGGG 17 6712 BCL11A-5082 + CGAGCAGGAGAGAAGGGGAG 20 6713 BCL11A-5083 - CGAGGUAAAAGAGAUAA 17 6714 BCL11A-5084 - CGAGGUAAAAGAGAUAAAGG 20 6715 BCL11A-5085 - CGCACUUGAACUUGCAGCUC 20 6716 BCL11A-5086 + CGCAGGGAAGAUGAAUU 17 6717 BCL11A-5087 + CGCCAGACGCGGCCCCC 17 6718 BCL11A-5088 + CGCCGCGGCGGUGGCGUGGC 20 6719 BCL11A-5089 + CGCGGCGGUGGCGUGGC 17 6720 BCL11A-5090 + CGCGGCGGUGGCGUGGCCGG 20 6721 BCL11A-5091 + CGGACGCCAGACGCGGCCCC 20 6722 BCL11A-5092 + CGGCAAUGGUUCCAGAUGGG 20 6723 BCL11A-5093 + CGGCCCCCGGGGGAGGG 17 6724 BCL11A-5094 - CGGCCCGCCCCUCCCCC 17 6725 BCL11A-5095 + CGGCGAGACAUGGUGGGCUG 20 6726 BCL11A-5096 + CGGCGGCGGCGGCGGCG 17 6727 BCL11A-5097 + CGGCGGCGGCGGCGGCGGCG 20 6728 BCL11A-5098 + CGGCGGUGGCGUGGCCGGGA 20 6729 BCL11A-5099 + CGGGCCGAGGGGAGGGGGCG 20 6730 BCL11A-5100 + CGGGCUCACCAGUGGCCGCA 20 6731 BCL11A-5101 + CGGGGAGGGGGAGGUGCGGG 20 6732 BCL11A-5102 + CGGGGGAGGGGCGGGCC 17 6733 BCL11A-5103 + CGGGGGAGGGGCGGGCCGAG 20 6734 BCL11A-5104 + CGGUGGCGUGGCCGGGA 17 6735 BCL11A-5105 + CGGUGGCGUGGCCGGGAGAG 20 6736 BCL11A-5106 - CUAGAAGCAAAAGCGAG 17 6737 BCL11A-5107 - CUAGAAGCAAAAGCGAGGGG 20 6738 BCL11A-5108 - CUCCUGACGUUCAAGUUCGC 20 6739 BCL11A-5109 - CUCGGCCCGCCCCUCCC 17 6740 BCL11A-5110 + CUCUUUUACCUCGACUC 17 6741 BCL11A-5111 - CUGACGUUCAAGUUCGC 17 6742 BCL11A-5112 + CUUGAACGUCAGGAGUCUGG 20 6743 BCL11A-5113 - CUUGAACUUGCAGCUCA 17 6744 BCL11A-5114 + CUUGCUUGCGGCGAGACAUG 20 6745 BCL11A-5115 - UAAUAAUUAUUAAUAAUCAC 20 6746 BCL11A-5116 + UAAUACAAAGAUGGCGC 17 6747 BCL11A-5117 - UAAUUAUUAAUAAUCAC 17 6748 BCL11A-5118 + UACACGGCAAUGGUUCCAGA 20 6749 BCL11A-5119 + UAGAAAGAAGGAGACUC 17 6750 BCL11A-5120 - UAGAAGCAAAAGCGAGG 17 6751 BCL11A-5121 - UAGAGUCCGCGUGUGUG 17 6752 BCL11A-5122 - UAGAGUCCGCGUGUGUGGGG 20 6753 BCL11A-5123 + UAUCUCUUUUACCUCGACUC 20 6754 BCL11A-5124 + UAUUAUUGGGUUACUUACGC 20 6755 BCL11A-5125 + UAUUGGGUUACUUACGC 17 6756 BCL11A-5126 + UCACACCAAUGGACACACAU 20 6757 BCL11A-5127 - UCACGAGAAAAACCUCC 17 6758 BCL11A-5128 + UCAGGAGUCUGGAUGGA 17 6759 BCL11A-5129 - UCAUUUUAGAGUCCGCGUGU 20 6760 BCL11A-5130 + UCCCGUUUGCUUAAGUG 17 6761 BCL11A-5131 - UCCGAGAGUCGAGGUAA 17 6762 BCL11A-5132 - UCCGCGUGUGUGGGGGGGAG 20 6763 BCL11A-5133 - UCGAGGUAAAAGAGAUA 17 6764 BCL11A-5134 - UCGAGGUAAAAGAGAUAAAG 20 6765 BCL11A-5135 - UCGGCCCGCCCCUCCCC 17 6766 BCL11A-5136 - UCUAACCCGGCUCUCCCGAU 20 6767 BCL11A-5137 + UCUCGGAGGUUUUUCUC 17 6768 BCL11A-5138 + UCUUUUACCUCGACUCU 17 6769 BCL11A-5139 + UGACAUCCAAAAUAAAU 17 6770 BCL11A-5140 - UGAUGAAGAUAUUUUCU 17 6771 BCL11A-5141 - UGCAUUUUUAAAUUUUUCAC 20 6772 BCL11A-5142 + UGCGGGGAGGGGGAGGU 17 6773 BCL11A-5143 + UGCUCCCCCCCACACAC 17 6774 BCL11A-5144 + UGGACACACAUCAGGGG 17 6775 BCL11A-5145 + UGGACAGAGACACACAAAAC 20 6776 BCL11A-5146 + UGGCAGGGGUGGGAGGA 17 6777 BCL11A-5147 + UGGCCAGUGCGGGGAGG 17 6778 BCL11A-5148 + UGGCCGGGAGAGAAGAA 17 6779 BCL11A-5149 + UGGCGCAGGGAAGAUGAAUU 20 6780 BCL11A-5150 + UGGCGUGGCCGGGAGAG 17 6781 BCL11A-5151 + UGGGAGGAAAGGGUGGG 17 6782 BCL11A-5152 + UGGGGUUUGCCUUGCUUGCG 20 6783 BCL11A-5153 - UGUAUUAUUUCUAAUUUAUU 20 6784 BCL11A-5154 - UUAAUAAUCACGAGAGCGCG 20 6785 BCL11A-5155 + UUAGAAAGAAGGAGACUCCA 20 6786 BCL11A-5156 - UUAGAGUCCGCGUGUGU 17 6787 BCL11A-5157 - UUAGAGUCCGCGUGUGUGGG 20 6788 BCL11A-5158 - UUGAACUUGCAGCUCAG 17 6789 BCL11A-5159 - UUGCCGUGUAUGCACUU 17 6790 BCL11A-5160 - UUGGAUGUCAAAAGGCACUG 20 6791 BCL11A-5161 - UUUAGAGUCCGCGUGUG 17 6792 BCL11A-5162 - UUUAGAGUCCGCGUGUGUGG 20 6793 BCL11A-5163 - UUUCACGAGAAAAACCU 17 6794 BCL11A-5164 - UUUUAGAGUCCGCGUGU 17 6795 BCL11A-5165 - UUUUAGAGUCCGCGUGUGUG 20 6796 BCL11A-5166 - UUUUCACGAGAAAAACCUCC 20 6797 BCL11A-5167 + UUUUGACAUCCAAAAUAAAU 20 6798

Table 12 provides exemplary targeting domains for knocking down expression of the BCL11A gene. The targeting domains bind between 500 bp upstream and 500 bp downstream of transcription start site. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidismeningitidis eiCas9 molecule to cause a steric block at the target region, e.g., between 500 bp upstream and 500 bp downstream of transcription start site to block transcription resulting in the repression of the BCL11A gene. Alternatively, any of the targeting domains in the table can be used with a N. meningitidismeningitidis eiCas9 fused to a transcriptional repressor to decrease transcription and therefore downregulate gene expression.

TABLE 12 DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO BCL11A-5168 + GCUUCUAGUCCUGCGCGCUC 20 6799 BCL11A-5169 + ACACACGCGGACUCUAAAAU 20 6800 BCL11A-5170 + UCUAGUCCUGCGCGCUC 17 6801 BCL11A-5171 + CACGCGGACUCUAAAAU 17 6802

Table 13A provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the first tier parameters. The targeting domains bind within 100 bp upstream and 100 bp downstream of the target position, good orthogonality and start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. Exemplary gRNA pairs are: HBB-9 and HBB-11, HBB-9 and HBB-39, HBB-20 and HBB-11 and HBB-20 and HBB-39.

TABLE 13A 1st Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO HBB-1 - GGUGCACCUGACUCCUG 17 6803 HBB-2 + GUAACGGCAGACUUCUCCAC 20 6804

Table 13B provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the second tier parameters. The targeting domains bind within 100 bp upstream and 100 bp downstream of the target position, good orthogonality and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

TABLE 13B 2nd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO HBB-3 + ACGGCAGACUUCUCCAC 17 6805 HBB-4 + ACUUCUCCACAGGAGUC 17 6806 HBB-5 + AGGAGUCAGGUGCACCA 17 6807 HBB-6 - CAUGGUGCACCUGACUCCUG 20 6808 HBB-7 + CACAGGAGUCAGGUGCACCA 20 6809 HBB-8 + CAGACUUCUCCACAGGAGUC 20 6810

Table 13C provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the third tier parameters. The targeting domains bind within 100 bp upstream and 100 bp downstream of the target position, and start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

TABLE 13C 3rd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO HBB-9 - GAAGUUGGUGGUGAGGCCCU 20 6811 HBB-10 - GCAACCUCAAACAGACACCA 20 6812 HBB-11 + GCCCCACAGGGCAGUAA 17 6813 HBB-12 - GCCGUUACUGCCCUGUG 17 6814 HBB-13 - GGAUGAAGUUGGUGGUG 17 6815 HBB-14 - GUCUGCCGUUACUGCCCUGU 20 6816 HBB-15 - GUGAACGUGGAUGAAGU 17 6817 HBB-16 - GUGAACGUGGAUGAAGUUGG 20 6818 HBB-17 - GUGGGGCAAGGUGAACG 17 6819 HBB-18 - GUGGUGAGGCCCUGGGC 17 6820 HBB-19 + GUUCACCUUGCCCCACA 17 6821 HBB-20 - GUUGGUGGUGAGGCCCU 17 6822

Table 13D provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the fourth tier parameters. The targeting domains bind within 100 bp upstream and 100 bp downstream of the target position, and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

Any of the targeting domains in the table can be used with a S. pyogenes Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

TABLE 13D 4th Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO HBB-21 - AACGUGGAUGAAGUUGG 17 6823 HBB-22 + AAGCAAAUGUAAGCAAUAGA 20 6824 HBB-23 - AAGGUGAACGUGGAUGAAGU 20 6825 HBB-24 + ACCAUGGUGUCUGUUUG 17 6826 HBB-25 - ACCUCAAACAGACACCA 17 6827 HBB-26 + ACCUUGAUACCAACCUGCCC 20 6828 HBB-27 - AGUCUGCCGUUACUGCCCUG 20 6829 HBB-28 - AGUUGGUGGUGAGGCCC 17 6830 HBB-29 + CAAAUGUAAGCAAUAGA 17 6831 HBB-30 + CACGUUCACCUUGCCCCACA 20 6832 HBB-31 + CCACGUUCACCUUGCCCCAC 20 6833 HBB-32 - CCCUGGGCAGGUUGGUAUCA 20 6834 HBB-33 - CCUGUGGGGCAAGGUGAACG 20 6835 HBB-34 + CCUUGAUACCAACCUGCCCA 20 6836 HBB-35 - CGUGGAUGAAGUUGGUGGUG 20 6837 HBB-36 - CGUUACUGCCCUGUGGGGCA 20 6838 HBB-37 + CGUUCACCUUGCCCCAC 17 6839 HBB-38 - CUGCCGUUACUGCCCUG 17 6840 HBB-39 + CUUGCCCCACAGGGCAGUAA 20 6841 HBB-40 - UACUGCCCUGUGGGGCA 17 6842 HBB-41 - UAUCAAGGUUACAAGAC 17 6843 HBB-42 - UCUGCCGUUACUGCCCUGUG 20 6844 HBB-43 - UGAAGUUGGUGGUGAGGCCC 20 6845 HBB-44 - UGAGGCCCUGGGCAGGU 17 6846 HBB-45 + UGAUACCAACCUGCCCA 17 6847 HBB-46 + UGCACCAUGGUGUCUGUUUG 20 6848 HBB-47 - UGCCGUUACUGCCCUGU 17 6849 HBB-48 - UGGGCAGGUUGGUAUCA 17 6850 HBB-49 - UGGUAUCAAGGUUACAAGAC 20 6851 HBB-50 - UGGUGAGGCCCUGGGCAGGU 20 6852 HBB-51 + UUGAUACCAACCUGCCC 17 6853 HBB-52 - UUGGUGGUGAGGCCCUGGGC 20 6854

Table 14A provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the first tier parameters. The targeting domains bind within 100 bp upstream and 100 bp downstream of the target position, good orthogonality and start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. Exemplary gRNA pairs are: HBB-9 and HBB-11, HBB-9 and HBB-39, HBB-20 and HBB-11 and HBB-20 and HBB-39.

TABLE 14A 1st Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO HBB-53 + GUAACGGCAGACUUCUCCAC 20 6855

Table 14B provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the second tier parameters. The targeting domains bind within 100 bp upstream and 100 bp downstream of the target position, good orthogonality and do not start with G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

TABLE 14B 2nd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO HBB-54 - CCCUGUGGGGCAAGGUGGAC 20 6856

Table 14C provides exemplary targeting domains for the E6V target site in the HBB gene selected according to the fifth tier parameters. The targeting domains bind within 100 bp upstream and 100 bp downstream of the target position and PAM is NNGRRV. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

Any of the targeting domains in the table can be used with a S. aureus Cas9 (nickase) molecule to generate a single strand break. In an embodiment, dual targeting is used to create two nicks on opposite DNA strands by using S. aureus Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp.

TABLE 14C 5th Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO HBB-55 - AGUCUGCCGUUACUGCCCUG 20 6857 HBB-56 - AAGUCUGCCGUUACUGCCCU 20 6858 HBB-57 + AACCUUGAUACCAACCUGCC 20 6859 HBB-58 + UCCACGUUCACCUUGCCCCA 20 6860 HBB-59 + GCUAGUGAACACAGUUGUGU 20 6861 HBB-60 - CCAUGGUGCACCUGACUCCU 20 6862 HBB-61 - CAUGGUGCACCUGACUCCUG 20 6863 HBB-62 + AGGUGCACCAUGGUGUCUGU 20 6864 HBB-63 - UGGUGCACCUGACUCCUGUG 20 6865 HBB-64 - GAACGUGGAUGAAGUUGGUG 20 6866 HBB-65 - UUACUGCCCUGUGGGGCAAG 20 6867 HBB-66 + GUGUCUGUUUGAGGUUGCUA 20 6868 HBB-67 - GUGGGGCAAGGUGAACGUGG 20 6869 HBB-68 - AUGAAGUUGGUGGUGAGGCC 20 6870 HBB-69 + AGUAACGGCAGACUUCUCCA 20 6871

Table 15A provides exemplary targeting domains for knocking out the BCL11A gene selected according to the first tier parameters. The targeting domains bind within the first 500 bp of the coding sequence (e.g., within 500 bp downstream from the start codon) and have a high level of orthogonality. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 15A 1st Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-5318 + UCAUCUCGAUUGGUGAA 17 6872 BCL11A-5319 + UUGCUUGCGGCGAGACA 17 6873 BCL11A-5320 - AUGUCUCGCCGCAAGCA 17 6874 BCL11A-5321 - GCAGAAUAUGCCCCGCA 17 6875 BCL11A-5322 - CCGUUGGGAGCUCCAGA 17 6876 BCL11A-5323 + CUCCAUGUGCAGAACGA 17 6877 BCL11A-5324 + UCGAUUGGUGAAGGGGA 17 6878 BCL11A-5325 + CAUCCUCUGGCGUGACC 17 6879 BCL11A-5326 - GCUCUAAUCCCCACGCC 17 6880 BCL11A-5327 + CCCGUUUGCUUAAGUGC 17 6881 BCL11A-5328 + AAACAAUCGUCAUCCUC 17 6882 BCL11A-5329 + CCCAACGGGCCGUGGUC 17 6883 BCL11A-5330 + CAUCUCGAUUGGUGAAG 17 6884 BCL11A-5331 - CAUCCAGGUCACGCCAG 17 6885 BCL11A-5332 - UUAUCAACGUCAUCUAG 17 6886 BCL11A-5333 + GAGCUCCCAACGGGCCG 17 6887 BCL11A-5334 + UGCACUCAUCCCAGGCG 17 6888 BCL11A-5335 + AGACAUGGUGGGCUGCG 17 6889 BCL11A-5336 + CGUUUGCUUAAGUGCUG 17 6890 BCL11A-5337 + GCUUUUUUCAUCUCGAU 17 6891 BCL11A-5338 + CCGUUUGCUUAAGUGCU 17 6892 BCL11A-5339 - UCCAAUCCCGUGGAGGU 17 6893 BCL11A-5340 + UUGCGGCGAGACAUGGU 17 6894 BCL11A-5341 - AUGACCUCCUCACCUGU 17 6895 BCL11A-5342 - UUAUUUUUAUCGAGCACAAA 20 6896 BCL11A-5343 + UCCCCUUCUGGAGCUCCCAA 20 6897 BCL11A-5344 + UUUUCAUCUCGAUUGGUGAA 20 6898 BCL11A-5345 + GCCUUGCUUGCGGCGAGACA 20 6899 BCL11A-5346 - ACCAUGUCUCGCCGCAAGCA 20 6900 BCL11A-5347 + GAGCUCCAUGUGCAGAACGA 20 6901 BCL11A-5348 - UCACAGAUAAACUUCUGCAC 20 6902 BCL11A-5349 + CGUCAUCCUCUGGCGUGACC 20 6903 BCL11A-5350 - GGAGCUCUAAUCCCCACGCC 20 6904 BCL11A-5351 - UCCCGUGGAGGUUGGCAUCC 20 6905 BCL11A-5352 + AUUCCCGUUUGCUUAAGUGC 20 6906 BCL11A-5353 + CCCCCAAUGGGAAGUUCAUC 20 6907 BCL11A-5354 + GCUCCCAACGGGCCGUGGUC 20 6908 BCL11A-5355 + UUUCAUCUCGAUUGGUGAAG 20 6909 BCL11A-5356 - UGUUUAUCAACGUCAUCUAG 20 6910 BCL11A-5357 + AGAGCUCCAUGUGCAGAACG 20 6911 BCL11A-5358 - GAAAAAAGCAUCCAAUCCCG 20 6912 BCL11A-5359 + GCGAGACAUGGUGGGCUGCG 20 6913 BCL11A-5360 - CAGAUAAACUUCUGCACUGG 20 6914 BCL11A-5361 + CGGCGAGACAUGGUGGGCUG 20 6915 BCL11A-5362 + CUGCACUCAUCCCAGGCGUG 20 6916 BCL11A-5363 - UGAACCAGACCACGGCCCGU 20 6917 BCL11A-5364 - GCAUCCAAUCCCGUGGAGGU 20 6918 BCL11A-5365 + UGCUUGCGGCGAGACAUGGU 20 6919 BCL11A-5366 + UCAAGAGGCUCGGCUGUGGU 20 6920 BCL11A-5367 - AUCAUGACCUCCUCACCUGU 20 6921

Table 15B provides exemplary targeting domains for knocking out the BCL11A gene selected according to the second tier parameters. The targeting domains bind within the first 500 bp of the coding sequence (e.g., within 500 bp downstream from the start codon). It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 15B 2nd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-5368 - UUUUUAUCGAGCACAAA 17 6922 BCL11A-5369 - CCCAGCACUUAAGCAAA 17 6923 BCL11A-5370 + AUAAGAAUGUCCCCCAA 17 6924 BCL11A-5371 + CCUUCUGGAGCUCCCAA 17 6925 BCL11A-5372 - AAACGGAAACAAUGCAA 17 6926 BCL11A-5373 + UUCAUCAUCUGUAAGAA 17 6927 BCL11A-5374 - CGUUGGGAGCUCCAGAA 17 6928 BCL11A-5375 - UCCCCUCGUUCUGCACA 17 6929 BCL11A-5376 - GAUGAUGAACCAGACCA 17 6930 BCL11A-5377 + CUGGAUGCCAACCUCCA 17 6931 BCL11A-5378 - CAGGUAAAUGAGAAGCA 17 6932 BCL11A-5379 - UAAACUUCUGCACUGGA 17 6933 BCL11A-5380 + UUCAUCUCGAUUGGUGA 17 6934 BCL11A-5381 + CAUUUGUAGAAGAAAUA 17 6935 BCL11A-5382 - AGGAAUUUGCCCCAAAC 17 6936 BCL11A-5383 - CCAGCACUUAAGCAAAC 17 6937 BCL11A-5384 + CUUCUGGAGCUCCCAAC 17 6938 BCL11A-5385 + CAUCUGGCACUGCCCAC 17 6939 BCL11A-5386 + UGGAUGCCAACCUCCAC 17 6940 BCL11A-5387 - CAGAUAAACUUCUGCAC 17 6941 BCL11A-5388 + UAUUCUGCACUCAUCCC 17 6942 BCL11A-5389 - CGUGGAGGUUGGCAUCC 17 6943 BCL11A-5390 - AAACAGGAACACAUAGC 17 6944 BCL11A-5391 - UGCAGAAUAUGCCCCGC 17 6945 BCL11A-5392 + AUGGUGGGCUGCGGGGC 17 6946 BCL11A-5393 + ACUUACAAAUACCCUGC 17 6947 BCL11A-5394 + UGUACAUGUGUAGCUGC 17 6948 BCL11A-5395 + GAGACAUGGUGGGCUGC 17 6949 BCL11A-5396 - GUGUUGUAUUAUUUUGC 17 6950 BCL11A-5397 + CCAAUGGGAAGUUCAUC 17 6951 BCL11A-5398 + AGGUCAUGAUCCCCUUC 17 6952 BCL11A-5399 + GUAAGAAUGGCUUCAAG 17 6953 BCL11A-5400 - GUUGGGAGCUCCAGAAG 17 6954 BCL11A-5401 + CAGCUUUUUCUAAGCAG 17 6955 BCL11A-5402 + UCCAUGUGCAGAACGAG 17 6956 BCL11A-2671 + CAGAACGAGGGGAGGAG 17 6957 BCL11A-5403 - AAACUUCUGCACUGGAG 17 6958 BCL11A-5404 + GCUCCAUGUGCAGAACG 17 6959 BCL11A-5405 - AAAAGCAUCCAAUCCCG 17 6960 BCL11A-5406 + CUUACAAAUACCCUGCG 17 6961 BCL11A-5407 + AUUGGUGAAGGGGAAGG 17 6962 BCL11A-5408 + ACUGCCCACAGGUGAGG 17 6963 BCL11A-4500 + GGGGCGGGCGGCGGCGG 17 6964 BCL11A-5409 + UGCGGGGCGGGCGGCGG 17 6965 BCL11A-5410 + GGCUGCGGGGCGGGCGG 17 6966 BCL11A-5411 + GUGGGCUGCGGGGCGGG 17 6967 BCL11A-5412 + AUGUGCAGAACGAGGGG 17 6968 BCL11A-5413 + CAUGGUGGGCUGCGGGG 17 6969 BCL11A-5414 + CUUGCGGCGAGACAUGG 17 6970 BCL11A-5415 - AUAAACUUCUGCACUGG 17 6971 BCL11A-5416 - AGCAUCCAAUCCCGUGG 17 6972 BCL11A-5417 - GAUGAACUUCCCAUUGG 17 6973 BCL11A-5418 - CAUGACCUCCUCACCUG 17 6974 BCL11A-5419 + AACUUACAAAUACCCUG 17 6975 BCL11A-5420 - CUGCUUAGAAAAAGCUG 17 6976 BCL11A-5421 + UUCAAGAGGCUCGGCUG 17 6977 BCL11A-5422 + CGAGACAUGGUGGGCUG 17 6978 BCL11A-5423 + CACUCAUCCCAGGCGUG 17 6979 BCL11A-5424 + GGCACUGCCCACAGGUG 17 6980 BCL11A-5425 - AGAUGAACUUCCCAUUG 17 6981 BCL11A-5426 + GGGGUUUGCCUUGCUUG 17 6982 BCL11A-5427 + CUAUGUGUUCCUGUUUG 17 6983 BCL11A-5428 + UAAGAAUGUCCCCCAAU 17 6984 BCL11A-5429 - CCAGAUGAACUUCCCAU 17 6985 BCL11A-5430 + GCCAACCUCCACGGGAU 17 6986 BCL11A-5431 + AUUAUUAUUACUAUUAU 17 6987 BCL11A-5432 - CUCUAAUCCCCACGCCU 17 6988 BCL11A-5433 + AAUGGCUUCAAGAGGCU 17 6989 BCL11A-5434 + GUACAUGUGUAGCUGCU 17 6990 BCL11A-5435 - ACCAGACCACGGCCCGU 17 6991 BCL11A-5436 + GCACUCAUCCCAGGCGU 17 6992 BCL11A-5437 + AGAGGCUCGGCUGUGGU 17 6993 BCL11A-5438 - CAGAUGAACUUCCCAUU 17 6994 BCL11A-5439 + UUAUUAUUACUAUUAUU 17 6995 BCL11A-5440 - CCAGACCACGGCCCGUU 17 6996 BCL11A-5441 + UGCUAUGUGUUCCUGUU 17 6997 BCL11A-5442 + GCUAUGUGUUCCUGUUU 17 6998 BCL11A-5443 - AACCCCAGCACUUAAGCAAA 20 6999 BCL11A-5444 + AAAAUAAGAAUGUCCCCCAA 20 7000 BCL11A-5445 - CACAAACGGAAACAAUGCAA 20 7001 BCL11A-5446 + UGGUUCAUCAUCUGUAAGAA 20 7002 BCL11A-5447 - GCCCGUUGGGAGCUCCAGAA 20 7003 BCL11A-5448 - UCCUCCCCUCGUUCUGCACA 20 7004 BCL11A-5449 - ACAGAUGAUGAACCAGACCA 20 7005 BCL11A-5450 + GACCUGGAUGCCAACCUCCA 20 7006 BCL11A-5451 - UAGCAGGUAAAUGAGAAGCA 20 7007 BCL11A-5452 - AGUGCAGAAUAUGCCCCGCA 20 7008 BCL11A-5453 - GGCCCGUUGGGAGCUCCAGA 20 7009 BCL11A-5454 + AUCUCGAUUGGUGAAGGGGA 20 7010 BCL11A-5455 - AGAUAAACUUCUGCACUGGA 20 7011 BCL11A-5456 + UUUUUCAUCUCGAUUGGUGA 20 7012 BCL11A-5457 - UAGAGGAAUUUGCCCCAAAC 20 7013 BCL11A-5458 - ACCCCAGCACUUAAGCAAAC 20 7014 BCL11A-5459 + CCCCUUCUGGAGCUCCCAAC 20 7015 BCL11A-5460 + GUUCAUCUGGCACUGCCCAC 20 7016 BCL11A-5461 + ACCUGGAUGCCAACCUCCAC 20 7017 BCL11A-5462 + GCAUAUUCUGCACUCAUCCC 20 7018 BCL11A-5463 - CCCAAACAGGAACACAUAGC 20 7019 BCL11A-5464 - GAGUGCAGAAUAUGCCCCGC 20 7020 BCL11A-5465 + GACAUGGUGGGCUGCGGGGC 20 7021 BCL11A-5466 + UCAACUUACAAAUACCCUGC 20 7022 BCL11A-5467 + AGUUGUACAUGUGUAGCUGC 20 7023 BCL11A-5468 + GGCGAGACAUGGUGGGCUGC 20 7024 BCL11A-5469 - UUGGUGUUGUAUUAUUUUGC 20 7025 BCL11A-5470 + GAUAAACAAUCGUCAUCCUC 20 7026 BCL11A-5471 + AGGAGGUCAUGAUCCCCUUC 20 7027 BCL11A-5472 + UCUGUAAGAAUGGCUUCAAG 20 7028 BCL11A-5473 - CCCGUUGGGAGCUCCAGAAG 20 7029 BCL11A-5474 - UGGCAUCCAGGUCACGCCAG 20 7030 BCL11A-5475 + CCACAGCUUUUUCUAAGCAG 20 7031 BCL11A-5476 + AGCUCCAUGUGCAGAACGAG 20 7032 BCL11A-5477 + GUGCAGAACGAGGGGAGGAG 20 7033 BCL11A-5478 - GAUAAACUUCUGCACUGGAG 20 7034 BCL11A-5479 + CUGGAGCUCCCAACGGGCCG 20 7035 BCL11A-5480 + UUCUGCACUCAUCCCAGGCG 20 7036 BCL11A-5481 + CAACUUACAAAUACCCUGCG 20 7037 BCL11A-5482 + UCGAUUGGUGAAGGGGAAGG 20 7038 BCL11A-5483 + GGCACUGCCCACAGGUGAGG 20 7039 BCL11A-5484 + UGCGGGGCGGGCGGCGGCGG 20 7040 BCL11A-5485 + GGCUGCGGGGCGGGCGGCGG 20 7041 BCL11A-5486 + GUGGGCUGCGGGGCGGGCGG 20 7042 BCL11A-5487 + AUGGUGGGCUGCGGGGCGGG 20 7043 BCL11A-5488 + UCCAUGUGCAGAACGAGGGG 20 7044 BCL11A-5489 + AGACAUGGUGGGCUGCGGGG 20 7045 BCL11A-5490 + UUGCUUGCGGCGAGACAUGG 20 7046 BCL11A-5491 - AAAAGCAUCCAAUCCCGUGG 20 7047 BCL11A-5492 - CCAGAUGAACUUCCCAUUGG 20 7048 BCL11A-5493 - GAUCAUGACCUCCUCACCUG 20 7049 BCL11A-5494 + CUCAACUUACAAAUACCCUG 20 7050 BCL11A-5495 - CCUCUGCUUAGAAAAAGCUG 20 7051 BCL11A-5496 + GGCUUCAAGAGGCUCGGCUG 20 7052 BCL11A-5497 + UCCCGUUUGCUUAAGUGCUG 20 7053 BCL11A-5498 + UCUGGCACUGCCCACAGGUG 20 7054 BCL11A-5499 - GCCAGAUGAACUUCCCAUUG 20 7055 BCL11A-5500 + GCUGGGGUUUGCCUUGCUUG 20 7056 BCL11A-5501 + CUGCUAUGUGUUCCUGUUUG 20 7057 BCL11A-5502 + AAAUAAGAAUGUCCCCCAAU 20 7058 BCL11A-5503 - GUGCCAGAUGAACUUCCCAU 20 7059 BCL11A-5504 + GAUGCUUUUUUCAUCUCGAU 20 7060 BCL11A-5505 + GAUGCCAACCUCCACGGGAU 20 7061 BCL11A-5506 - GAGCUCUAAUCCCCACGCCU 20 7062 BCL11A-5507 + AAGAAUGGCUUCAAGAGGCU 20 7063 BCL11A-5508 + GUUGUACAUGUGUAGCUGCU 20 7064 BCL11A-5509 + UUCCCGUUUGCUUAAGUGCU 20 7065 BCL11A-5510 + UCUGCACUCAUCCCAGGCGU 20 7066 BCL11A-5511 - UGCCAGAUGAACUUCCCAUU 20 7067 BCL11A-5512 - GAACCAGACCACGGCCCGUU 20 7068 BCL11A-5513 + ACCUGCUAUGUGUUCCUGUU 20 7069 BCL11A-5514 + CCUGCUAUGUGUUCCUGUUU 20 7070

Table 15C provides exemplary targeting domains for knocking out the BCL11A gene selected according to the third tier parameters. The targeting domains fall in the coding sequence of the gene, downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon of the gene). It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 15C 3rd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-5515 + UCCGACGAGGAGGCAAA 17 7071 BCL11A-5516 + AUUCUUAGCAGGUUAAA 17 7072 BCL11A-5517 - GCUGCGGUUGAAUCCAA 17 7073 BCL11A-5518 - GGCCCAGCCCUAUGCAA 17 7074 BCL11A-5519 + CCGCAGCACCCUGUCAA 17 7075 BCL11A-5520 - CUUCCGGCCUGGCAGAA 17 7076 BCL11A-5521 + UUGAUGCGCUUAGAGAA 17 7077 BCL11A-5522 - AACCUGAUCCCGGAGAA 17 7078 BCL11A-5523 - GAGCACUCCUCGGAGAA 17 7079 BCL11A-5524 + CUGGGUACUACGCCGAA 17 7080 BCL11A-5525 + UCUCCGAAGCUAAGGAA 17 7081 BCL11A-5526 + GGGGGCGUCGCCAGGAA 17 7082 BCL11A-5527 + UUGCUACCUGGCUGGAA 17 7083 BCL11A-5528 + CUGCACCUAGUCCUGAA 17 7084 BCL11A-5529 + AACCAUGCACUGGUGAA 17 7085 BCL11A-5530 + AUUUUCUCAGAACUUAA 17 7086 BCL11A-5531 + UAUUCUUAGCAGGUUAA 17 7087 BCL11A-5532 - GACGAUGGCACUGUUAA 17 7088 BCL11A-5533 + CGGUGGUGGACUAAACA 17 7089 BCL11A-5534 - GGCCGCGAUGCCCAACA 17 7090 BCL11A-5535 - UACUUAGAAAGCGAACA 17 7091 BCL11A-2969 - GCACCGGCGCAGCCACA 17 7092 BCL11A-2924 - CGAGGCCGAGGGCCACA 17 7093 BCL11A-5536 - CCCGAGUGCCUUUGACA 17 7094 BCL11A-5537 + CUUGAACUUGGCCACCA 17 7095 BCL11A-5538 - AAAAUUUGAAGCCCCCA 17 7096 BCL11A-5539 + CUGCAAUAUGAAUCCCA 17 7097 BCL11A-5540 - UAUGGAGCCUCCCGCCA 17 7098 BCL11A-5541 + CGGGUGAUGGGUGGCCA 17 7099 BCL11A-5542 + UCUCCUAGAGAAAUCCA 17 7100 BCL11A-5543 - UCCCAGCCACCUCUCCA 17 7101 BCL11A-5544 - CUCGGGGCGCAGCGGCA 17 7102 BCL11A-5545 - CGACGUCAUGCAGGGCA 17 7103 BCL11A-5546 + CUGCAUGACGUCGGGCA 17 7104 BCL11A-5547 - GACUUAGAGAGCUGGCA 17 7105 BCL11A-5548 - CUGCCCGACGUCAUGCA 17 7106 BCL11A-5549 + CUCGCUGAAGUGCUGCA 17 7107 BCL11A-5550 - AGCCAUUCACCAGUGCA 17 7108 BCL11A-5551 - CACGCACAGAACACUCA 17 7109 BCL11A-5552 + GUCGGACUUGACCGUCA 17 7110 BCL11A-5553 + ACCAACCCGCGGGGUCA 17 7111 BCL11A-5554 - AGGCCCAGCUCAAAAGA 17 7112 BCL11A-5555 - GCUUCCGGCCUGGCAGA 17 7113 BCL11A-5556 - CCUGGGGGCGGAAGAGA 17 7114 BCL11A-5557 + CUUGAUGCGCUUAGAGA 17 7115 BCL11A-5558 - GCUGACGGAGAGCGAGA 17 7116 BCL11A-5559 - GCGCAUCAAGCUCGAGA 17 7117 BCL11A-5560 - UCGGACCGCAUAGACGA 17 7118 BCL11A-5561 - ACGGUCAAGUCCGACGA 17 7119 BCL11A-5562 - CACCUGGCCGAGGCCGA 17 7120 BCL11A-5563 + GUCUCCGAAGCUAAGGA 17 7121 BCL11A-5564 + GGGGGGCGUCGCCAGGA 17 7122 BCL11A-5565 + AGGUUGGAGACAGAGGA 17 7123 BCL11A-5566 + GGGCGGAUUGCAGAGGA 17 7124 BCL11A-5567 + GGGGCUGGGAGGGAGGA 17 7125 BCL11A-5568 - CCGGGGAGCUGGACGGA 17 7126 BCL11A-5569 - GUGUGGCAGUUUUCGGA 17 7127 BCL11A-5570 + GGAUUGCAGAGGAGGGA 17 7128 BCL11A-5571 + UUGACCGGGGGCUGGGA 17 7129 BCL11A-5572 + UGGAGAGGUGGCUGGGA 17 7130 BCL11A-5573 - CCGCCCGGGGAGCUGGA 17 7131 BCL11A-5574 - GCGGCACGGGAAGUGGA 17 7132 BCL11A-5575 + GCCCAGGACCUGGUGGA 17 7133 BCL11A-5576 - CAAAUCGUCCCCCAUGA 17 7134 BCL11A-5577 + UCUGCACCUAGUCCUGA 17 7135 BCL11A-5578 - GGAGGAGGAGGAGCUGA 17 7136 BCL11A-5579 + CAAAGGCACUCGGGUGA 17 7137 BCL11A-5580 + GGCCCGGACCACUAAUA 17 7138 BCL11A-5581 + GCAGUAACCUUUGCAUA 17 7139 BCL11A-5582 - AGCGAGAGGGUGGACUA 17 7140 BCL11A-5583 + UGGAGUCUCCGAAGCUA 17 7141 BCL11A-5584 - GUUGAAUCCAAUGGCUA 17 7142 BCL11A-5585 + CACAGGUUGCACUUGUA 17 7143 BCL11A-5586 + AAUUUUCUCAGAACUUA 17 7144 BCL11A-5587 + UCGGUGGUGGACUAAAC 17 7145 BCL11A-5588 - ACCUGAUCCCGGAGAAC 17 7146 BCL11A-5589 - AGCACUCCUCGGAGAAC 17 7147 BCL11A-2979 - CACCGGCGCAGCCACAC 17 7148 BCL11A-2916 - CCGAGGCCGAGGGCCAC 17 7149 BCL11A-5590 + UGCACGCGUGGUCGCAC 17 7150 BCL11A-5591 - UCGGGGCGCAGCGGCAC 17 7151 BCL11A-5592 + CAAGAGAAACCAUGCAC 17 7152 BCL11A-5593 - GCAACCUGGUGGUGCAC 17 7153 BCL11A-5594 + GCAGCAGCUUUUUGGAC 17 7154 BCL11A-5595 + CAUGACUUGGACUUGAC 17 7155 BCL11A-5596 - ACCCGAGUGCCUUUGAC 17 7156 BCL11A-5597 - CAAAUUUCAGAGCAACC 17 7157 BCL11A-5598 - GCCAGCUCCCCGGAACC 17 7158 BCL11A-5599 + UGCGCCGGUGCACCACC 17 7159 BCL11A-5600 - GCAUAAGCGCGGCCACC 17 7160 BCL11A-5601 - CAGCGAGGCCUUCCACC 17 7161 BCL11A-5602 + GCUUCUCGCCCAGGACC 17 7162 BCL11A-5603 + AUGACUUGGACUUGACC 17 7163 BCL11A-5604 - AACCUGCUAAGAAUACC 17 7164 BCL11A-5605 + AAGGGCGGCUUGCUACC 17 7165 BCL11A-5606 - CGACCACGCGUGCACCC 17 7166 BCL11A-5607 - GAAAAUUUGAAGCCCCC 17 7167 BCL11A-5608 + CCAUCUCUUCCGCCCCC 17 7168 BCL11A-5609 - UCCUCCCUCCCAGCCCC 17 7169 BCL11A-5610 - GGAGUUCGACCUGCCCC 17 7170 BCL11A-5611 + CCUCCGUCCAGCUCCCC 17 7171 BCL11A-5612 - GGCCGCGGCUGCUCCCC 17 7172 BCL11A-5613 - AGCCCACCGCUGUCCCC 17 7173 BCL11A-5614 - GCUUCUCCACACCGCCC 17 7174 BCL11A-5615 + CCGAGGCCGACUCGCCC 17 7175 BCL11A-5616 + GCUUAUGCUUCUCGCCC 17 7176 BCL11A-5617 - AUUAGUGGUCCGGGCCC 17 7177 BCL11A-5618 - GGCGGAAGAGAUGGCCC 17 7178 BCL11A-5619 + UUGAGCUGGGCCUGCCC 17 7179 BCL11A-5620 - CUCCACCGCCAGCUCCC 17 7180 BCL11A-5621 + CCCUCCGUCCAGCUCCC 17 7181 BCL11A-5622 - UGGCCGCGGCUGCUCCC 17 7182 BCL11A-5623 - CUGCAACCAUUCCAGCC 17 7183 BCL11A-5624 - CGGCUUCGGGCUGAGCC 17 7184 BCL11A-5625 - CGCUUCUCCACACCGCC 17 7185 BCL11A-5626 - CCACCGCAUAGAGCGCC 17 7186 BCL11A-5627 + CCCGAGGCCGACUCGCC 17 7187 BCL11A-5628 + GGAGGGGGGGCGUCGCC 17 7188 BCL11A-5629 + AUAGGGCUGGGCCGGCC 17 7189 BCL11A-5630 - GAGAGAGGCUUCCGGCC 17 7190 BCL11A-5631 + UGUUGGGCAUCGCGGCC 17 7191 BCL11A-5632 + GGCCCUCGGCCUCGGCC 17 7192 BCL11A-5633 + CUGGGCCUGCCCGGGCC 17 7193 BCL11A-5634 - UAUUAGUGGUCCGGGCC 17 7194 BCL11A-5635 + GCUUCAGCUUGCUGGCC 17 7195 BCL11A-5636 + UCGGGUGAUGGGUGGCC 17 7196 BCL11A-5637 + UUUGAGCUGGGCCUGCC 17 7197 BCL11A-5638 + GGGAUCUUUGAGCUGCC 17 7198 BCL11A-5639 + GAAAGCGCCCUUCUGCC 17 7199 BCL11A-5640 + ACCAAGUCGCUGGUGCC 17 7200 BCL11A-5641 + UCUCUCGAUACUGAUCC 17 7201 BCL11A-5642 - CGACCCCAACCUGAUCC 17 7202 BCL11A-5643 + GGUGGCGCGCCGCCUCC 17 7203 BCL11A-5644 - CCGGCUACGCGGCCUCC 17 7204 BCL11A-5645 + CCUCGUCCCCGUUCUCC 17 7205 BCL11A-5646 - GGCCUUCCACCAGGUCC 17 7206 BCL11A-5647 - CCCCAUAUUAGUGGUCC 17 7207 BCL11A-5648 - UAGCAAGCCGCCCUUCC 17 7208 BCL11A-5649 + CGCUGGUGCCGGGUUCC 17 7209 BCL11A-5650 - UAGGAGACUUAGAGAGC 17 7210 BCL11A-5651 + GAAGGGGCUCAGCGAGC 17 7211 BCL11A-2886 - CACACCGCCCGGGGAGC 17 7212 BCL11A-5652 + GCCGGGUUCCGGGGAGC 17 7213 BCL11A-5653 + UCUGCCCUCUUUUGAGC 17 7214 BCL11A-5654 + CCUGGAGGCCGCGUAGC 17 7215 BCL11A-5655 + AUCCUGGUAUUCUUAGC 17 7216 BCL11A-5656 + AAGGGAUACCAACCCGC 17 7217 BCL11A-5657 - AAGUCCCCUGACCCCGC 17 7218 BCL11A-5658 + CGCCCGUGUGGCUGCGC 17 7219 BCL11A-5659 + UAUGCGGUCCGACUCGC 17 7220 BCL11A-5660 - CCACGAGAACAGCUCGC 17 7221 BCL11A-5661 - UACUCGCAGUGGCUCGC 17 7222 BCL11A-5662 + GCUGCCCACCAAGUCGC 17 7223 BCL11A-5663 - CACCGCUGUCCCCAGGC 17 7224 BCL11A-5664 + GCGCCCUUCUGCCAGGC 17 7225 BCL11A-5665 + GUGUUGGGCAUCGCGGC 17 7226 BCL11A-5666 + UAACCUUUGCAUAGGGC 17 7227 BCL11A-5667 - GUGGUCCGGGCCCGGGC 17 7228 BCL11A-5668 + CCUGCAUGACGUCGGGC 17 7229 BCL11A-5669 + UGGACUUGACCGGGGGC 17 7230 BCL11A-5670 + GCAUCGCGGCCGGGGGC 17 7231 BCL11A-5671 + UUUGCAUAGGGCUGGGC 17 7232 BCL11A-5672 + CUAGAGAAAUCCAUGGC 17 7233 BCL11A-5673 + GCGGCUUGCUACCUGGC 17 7234 BCL11A-5674 - AGACUUAGAGAGCUGGC 17 7235 BCL11A-5675 + UCCCAUGGAGAGGUGGC 17 7236 BCL11A-5676 - GACGAAGACUCGGUGGC 17 7237 BCL11A-5677 - CCUGCCCGACGUCAUGC 17 7238 BCL11A-5394 + UGUACAUGUGUAGCUGC 17 7239 BCL11A-5678 + GGACUUGAGCGCGCUGC 17 7240 BCL11A-5679 - GUCCAAAAAGCUGCUGC 17 7241 BCL11A-5680 + CACCAAGUCGCUGGUGC 17 7242 BCL11A-5681 + GUGGCGCUUCAGCUUGC 17 7243 BCL11A-5682 + CCCCGUUCUCCGGGAUC 17 7244 BCL11A-5683 + CCCUGUCAAAGGCACUC 17 7245 BCL11A-5684 - CCGGGCGAGUCGGCCUC 17 7246 BCL11A-5685 - CUGGACGGAGGGAUCUC 17 7247 BCL11A-5686 + ACACAUCUUGAGCUCUC 17 7248 BCL11A-5687 + UCCUCGUCCCCGUUCUC 17 7249 BCL11A-5688 + AUGCCCUGCAUGACGUC 17 7250 BCL11A-5689 + UACCAACCCGCGGGGUC 17 7251 BCL11A-5690 - GCCCCAUAUUAGUGGUC 17 7252 BCL11A-5691 + GGCAAAAGGCGAUUGUC 17 7253 BCL11A-5692 - CGGGUUGGUAUCCCUUC 17 7254 BCL11A-5693 - GUAUCGAGAGAGGCUUC 17 7255 BCL11A-5694 - GGGUGGACUACGGCUUC 17 7256 BCL11A-5695 + UCGCUGGUGCCGGGUUC 17 7257 BCL11A-5696 - CAGGCCCAGCUCAAAAG 17 7258 BCL11A-5697 + GUGAAGAACCUAGAAAG 17 7259 BCL11A-5698 + UUCUUAGCAGGUUAAAG 17 7260 BCL11A-3087 - CGAGGAAGAGGAAGAAG 17 7261 BCL11A-5699 + UGAUGCGCUUAGAGAAG 17 7262 BCL11A-3083 - GGAGGACGACGAGGAAG 17 7263 BCL11A-3089 - GGAAGAAGAGGAGGAAG 17 7264 BCL11A-3075 - CGGGGACGAGGAGGAAG 17 7265 BCL11A-2876 - CGCAGCGGCACGGGAAG 17 7266 BCL11A-5700 + GGUGGUGGACUAAACAG 17 7267 BCL11A-5701 + AAAGAGGUUGGAGACAG 17 7268 BCL11A-5702 + GGCCGGCCUGGGGACAG 17 7269 BCL11A-5703 - AAAUUUGAAGCCCCCAG 17 7270 BCL11A-5704 - GGGAUCUCGGGGCGCAG 17 7271 BCL11A-5705 - AGAACGUGUACUCGCAG 17 7272 BCL11A-5706 + GGAGGGGCGGAUUGCAG 17 7273 BCL11A-5707 + CCAACCCGCGGGGUCAG 17 7274 BCL11A-5708 - AGGAUCAGUAUCGAGAG 17 7275 BCL11A-5709 - AGCUGACGGAGAGCGAG 17 7276 BCL11A-5710 + GGUUGGAGACAGAGGAG 17 7277 BCL11A-5711 + GGGCUGGGAGGGAGGAG 17 7278 BCL11A-5712 + GAUUGCAGAGGAGGGAG 17 7279 BCL11A-5713 + ACUAAACAGGGGGGGAG 17 7280 BCL11A-5714 + AUAUGAAUCCCAUGGAG 17 7281 BCL11A-5715 - AGCACGCCCCAUAUUAG 17 7282 BCL11A-5716 - CCUGAUCCCGGAGAACG 17 7283 BCL11A-3081 - GGAAGAGGAGGACGACG 17 7284 BCL11A-5717 + CGAGGAGUGCUCCGACG 17 7285 BCL11A-2837 - CCCGGAGAACGGGGACG 17 7286 BCL11A-5718 - GUGGCUCGCCGGCUACG 17 7287 BCL11A-5719 + UGACUUGGACUUGACCG 17 7288 BCL11A-5720 + GAAGGGAUACCAACCCG 17 7289 BCL11A-5721 - GAAGUCCCCUGACCCCG 17 7290 BCL11A-5722 + UUUGGACAGGCCCCCCG 17 7291 BCL11A-5723 - CUUCUCCACACCGCCCG 17 7292 BCL11A-5724 + CGAGGCCGACUCGCCCG 17 7293 BCL11A-2946 + CGCCCGGGGAGCAGCCG 17 7294 BCL11A-5725 - CCACCUGGCCGAGGCCG 17 7295 BCL11A-5726 + GUUGGGCAUCGCGGCCG 17 7296 BCL11A-5727 - GGCACUGUUAAUGGCCG 17 7297 BCL11A-5728 - GCGCGGCCACCUGGCCG 17 7298 BCL11A-5729 + CAAACUCCCGUUCUCCG 17 7299 BCL11A-5730 - CAGCGCGCUCAAGUCCG 17 7300 BCL11A-5731 + GCUGGUGCCGGGUUCCG 17 7301 BCL11A-5732 - GGCGAGAAGCAUAAGCG 17 7302 BCL11A-5733 - CAUGCAGCACUUCAGCG 17 7303 BCL11A-5734 + UGGCCUGGGUGCACGCG 17 7304 BCL11A-5735 + AGGGAUACCAACCCGCG 17 7305 BCL11A-5736 - CACGAGAACAGCUCGCG 17 7306 BCL11A-5737 + UGACGUCGGGCAGGGCG 17 7307 BCL11A-5738 - GAACAGCUCGCGGGGCG 17 7308 BCL11A-5739 - GGGCGCGGUCGUGGGCG 17 7309 BCL11A-5740 + CUCCGUGUUGGGCAUCG 17 7310 BCL11A-5741 - CGGGCGAGUCGGCCUCG 17 7311 BCL11A-5742 - ACCACGAGAACAGCUCG 17 7312 BCL11A-5743 - UGGACGGAGGGAUCUCG 17 7313 BCL11A-5744 + CCCGCGAGCUGUUCUCG 17 7314 BCL11A-5745 - CUCGCGGGGCGCGGUCG 17 7315 BCL11A-5746 + GUGGUGGACUAAACAGG 17 7316 BCL11A-5747 + CCUCGGCCUCGGCCAGG 17 7317 BCL11A-3090 - GGAAGAGGAAGAAGAGG 17 7318 BCL11A-3091 - AGAAGAGGAGGAAGAGG 17 7319 BCL11A-3088 - GGACGAGGAGGAAGAGG 17 7320 BCL11A-5748 + GAGGUUGGAGACAGAGG 17 7321 BCL11A-5749 + GGGGCGGAUUGCAGAGG 17 7322 BCL11A-5750 + UGAAUCCCAUGGAGAGG 17 7323 BCL11A-5751 + GGAGUGCUCCGACGAGG 17 7324 BCL11A-3066 - GGAGAACGGGGACGAGG 17 7325 BCL11A-3092 - AGAGGAGGAAGAGGAGG 17 7326 BCL11A-5752 + GUUGGAGACAGAGGAGG 17 7327 BCL11A-3093 - GGAGGAAGAGGAGGAGG 17 7328 BCL11A-5753 + AUUGCAGAGGAGGGAGG 17 7329 BCL11A-5754 + GGGGGCUGGGAGGGAGG 17 7330 BCL11A-5755 - CGGGCUGAGCCUGGAGG 17 7331 BCL11A-5756 - CCCGGGGAGCUGGACGG 17 7332 BCL11A-5757 + GACUUGGACUUGACCGG 17 7333 BCL11A-5758 + UUGGGCAUCGCGGCCGG 17 7334 BCL11A-5759 + CGGCCUGGGGACAGCGG 17 7335 BCL11A-5760 + UUCCGGGGAGCUGGCGG 17 7336 BCL11A-5761 + CCAGGCGCUCUAUGCGG 17 7337 BCL11A-5762 - UUGCGACGAAGACUCGG 17 7338 BCL11A-5763 - GGGCGAGUCGGCCUCGG 17 7339 BCL11A-5764 + UCCAAGUGAUGUCUCGG 17 7340 BCL11A-5765 + GGCGUCGCCAGGAAGGG 17 7341 BCL11A-5766 + UGGUGGACUAAACAGGG 17 7342 BCL11A-3076 - GACGGAGAGCGAGAGGG 17 7343 BCL11A-5767 + CGGAUUGCAGAGGAGGG 17 7344 BCL11A-5768 + UUGCAGAGGAGGGAGGG 17 7345 BCL11A-5769 + ACCGGGGGCUGGGAGGG 17 7346 BCL11A-5770 + CCGUCCAGCUCCCCGGG 17 7347 BCL11A-5771 + GAGAAAUCCAUGGCGGG 17 7348 BCL11A-5772 - GGCGAGUCGGCCUCGGG 17 7349 BCL11A-5773 + GGUGGACUAAACAGGGG 17 7350 BCL11A-5774 - UUUGAAGCCCCCAGGGG 17 7351 BCL11A-5775 + CUGGGAGGGAGGAGGGG 17 7352 BCL11A-5776 + UGCAGAGGAGGGAGGGG 17 7353 BCL11A-5777 - CAUAGAGCGCCUGGGGG 17 7354 BCL11A-5778 - AGCCCCCAGGGGUGGGG 17 7355 BCL11A-5779 + GGCACUCGGGUGAUGGG 17 7356 BCL11A-5780 + CUUGACCGGGGGCUGGG 17 7357 BCL11A-5781 + AACAGGGGGGGAGUGGG 17 7358 BCL11A-5782 + GGUACUACGCCGAAUGG 17 7359 BCL11A-5783 + CCUAGAGAAAUCCAUGG 17 7360 BCL11A-5784 + GGACUUGACCGUCAUGG 17 7361 BCL11A-5785 - AUUUCAGAGCAACCUGG 17 7362 BCL11A-5786 + UCUCGCCCAGGACCUGG 17 7363 BCL11A-5787 - CUUCGGGCUGAGCCUGG 17 7364 BCL11A-5788 - CCGCAUAGAGCGCCUGG 17 7365 BCL11A-5789 + AUCUUUGAGCUGCCUGG 17 7366 BCL11A-5790 + GGGUUCCGGGGAGCUGG 17 7367 BCL11A-5791 - AGCGGCACGGGAAGUGG 17 7368 BCL11A-5792 - CGCGCUCAAGUCCGUGG 17 7369 BCL11A-5793 + GCGAGCUGUUCUCGUGG 17 7370 BCL11A-5794 + GGCGCUCUAUGCGGUGG 17 7371 BCL11A-5795 + AAGUGAUGUCUCGGUGG 17 7372 BCL11A-5796 - CGGCACCAGCGACUUGG 17 7373 BCL11A-5797 + GGGUACUACGCCGAAUG 17 7374 BCL11A-5798 + CGGACUUGACCGUCAUG 17 7375 BCL11A-5799 + GCAUGUGCGUCUUCAUG 17 7376 BCL11A-5800 + CCCGGACCACUAAUAUG 17 7377 BCL11A-5801 + CCCCCAGGCGCUCUAUG 17 7378 BCL11A-5802 + CAGUGCCAUCGUCUAUG 17 7379 BCL11A-5803 - GACACUUGUGAGUACUG 17 7380 BCL11A-5804 + CGUCGCAAGUGUCCCUG 17 7381 BCL11A-5805 - ACCGCAUAGAGCGCCUG 17 7382 BCL11A-5806 + AGGGCUGGGCCGGCCUG 17 7383 BCL11A-5807 + AGGGGCUCAGCGAGCUG 17 7384 BCL11A-5808 - CCUUUGACAGGGUGCUG 17 7385 BCL11A-5809 - AAGUCAUGCGAGUUCUG 17 7386 BCL11A-5810 + AGGGCUUCUCGCCCGUG 17 7387 BCL11A-5811 + CAGCUCCCCGGGCGGUG 17 7388 BCL11A-5812 + AGGCGCUCUAUGCGGUG 17 7389 BCL11A-5813 - UGAAGCCCCCAGGGGUG 17 7390 BCL11A-5814 - AGAGAGCUCAAGAUGUG 17 7391 BCL11A-5815 + UCUCCGGGAUCAGGUUG 17 7392 BCL11A-5816 + UGGGUACUACGCCGAAU 17 7393 BCL11A-5817 + GGAGGCUCCAUAGCCAU 17 7394 BCL11A-5818 - CCCAGCCACCUCUCCAU 17 7395 BCL11A-5819 + UGCAGUAACCUUUGCAU 17 7396 BCL11A-5820 + UCGGACUUGACCGUCAU 17 7397 BCL11A-5821 + AAAGGCACUCGGGUGAU 17 7398 BCL11A-5822 + GCCCGGACCACUAAUAU 17 7399 BCL11A-5823 + GUUCUCGCUCUUGAACU 17 7400 BCL11A-5824 + ACCCUGUCAAAGGCACU 17 7401 BCL11A-5825 - ACCACCGAGACAUCACU 17 7402 BCL11A-5826 - CACUUGCGACGAAGACU 17 7403 BCL11A-5827 - ACCCGGCACCAGCGACU 17 7404 BCL11A-5828 - GGUAUCCCUUCAGGACU 17 7405 BCL11A-5829 + GCAGAACUCGCAUGACU 17 7406 BCL11A-5830 + AGUGUCCCUGUGGCCCU 17 7407 BCL11A-5831 - CACCGCAUAGAGCGCCU 17 7408 BCL11A-5832 + UAGGGCUGGGCCGGCCU 17 7409 BCL11A-5833 + CCUGUGGCCCUCGGCCU 17 7410 BCL11A-5834 - CCCGGGCGAGUCGGCCU 17 7411 BCL11A-5835 + CUUCAGCUUGCUGGCCU 17 7412 BCL11A-5836 - CUCGUCGGAGCACUCCU 17 7413 BCL11A-5837 - GCCUUCCACCAGGUCCU 17 7414 BCL11A-5838 + AAGGGGCUCAGCGAGCU 17 7415 BCL11A-5839 + CUGCCCUCUUUUGAGCU 17 7416 BCL11A-5840 + AACCUUUGCAUAGGGCU 17 7417 BCL11A-5841 + GGACUUGACCGGGGGCU 17 7418 BCL11A-5842 + CCCAUGGAGAGGUGGCU 17 7419 BCL11A-5434 + GUACAUGUGUAGCUGCU 17 7420 BCL11A-5843 - UCCAAAAAGCUGCUGCU 17 7421 BCL11A-5844 - GCUGGACGGAGGGAUCU 17 7422 BCL11A-5845 + CACAUCUUGAGCUCUCU 17 7423 BCL11A-5846 - CCGCCAUGGAUUUCUCU 17 7424 BCL11A-5847 + GGGUCCAAGUGAUGUCU 17 7425 BCL11A-5848 - GUCUCCAACCUCUUUCU 17 7426 BCL11A-5849 - CUCGGUGGCCGGCGAGU 17 7427 BCL11A-5850 - CUGCUCCCCGGGCGAGU 17 7428 BCL11A-5851 + CUAAACAGGGGGGGAGU 17 7429 BCL11A-5852 + CAUGCCCUGCAUGACGU 17 7430 BCL11A-5853 - GGCGCGGUCGUGGGCGU 17 7431 BCL11A-5854 - GCCUUUUGCCUCCUCGU 17 7432 BCL11A-5855 + GGUGGAGAGACCGUCGU 17 7433 BCL11A-5856 - UCGCGGGGCGCGGUCGU 17 7434 BCL11A-5857 + GUUCUCCGGGAUCAGGU 17 7435 BCL11A-5858 + AGAACCUAGAAAGAGGU 17 7436 BCL11A-5859 + GGCCUGGGGACAGCGGU 17 7437 BCL11A-5860 + CAGGCGCUCUAUGCGGU 17 7438 BCL11A-5861 - CCCCUGACCCCGCGGGU 17 7439 BCL11A-5862 - UUGAAGCCCCCAGGGGU 17 7440 BCL11A-5863 - GGCACCAGCGACUUGGU 17 7441 BCL11A-5864 - ACACUUGUGAGUACUGU 17 7442 BCL11A-5865 + GUACACGUUCUCCGUGU 17 7443 BCL11A-5866 + GCACAGGUUGCACUUGU 17 7444 BCL11A-5867 - CUUCACACACCCCCAUU 17 7445 BCL11A-5868 - GAUCCCUUCCUUAGCUU 17 7446 BCL11A-5869 - AGGGUGGACUACGGCUU 17 7447 BCL11A-5870 + UUCUCCGGGAUCAGGUU 17 7448 BCL11A-5871 + UACACGUUCUCCGUGUU 17 7449 BCL11A-5872 + GCCCAGCAGCAGCUUUU 17 7450 BCL11A-5873 - AGAUGUGUGGCAGUUUU 17 7451 BCL11A-5874 + UGCUCCGACGAGGAGGCAAA 20 7452 BCL11A-5875 + GGUAUUCUUAGCAGGUUAAA 20 7453 BCL11A-5876 - GGUGCUGCGGUUGAAUCCAA 20 7454 BCL11A-5877 - GCCGGCCCAGCCCUAUGCAA 20 7455 BCL11A-5878 + CAACCGCAGCACCCUGUCAA 20 7456 BCL11A-5879 - AGGCUUCCGGCCUGGCAGAA 20 7457 BCL11A-5880 + AGCUUGAUGCGCUUAGAGAA 20 7458 BCL11A-5881 - CCCAACCUGAUCCCGGAGAA 20 7459 BCL11A-5882 - UCGGAGCACUCCUCGGAGAA 20 7460 BCL11A-5883 + UCUCUGGGUACUACGCCGAA 20 7461 BCL11A-5884 + GAGUCUCCGAAGCUAAGGAA 20 7462 BCL11A-5885 + AGGGGGGGCGUCGCCAGGAA 20 7463 BCL11A-5886 + GGCUUGCUACCUGGCUGGAA 20 7464 BCL11A-5887 + AUUCUGCACCUAGUCCUGAA 20 7465 BCL11A-5888 + AGAAACCAUGCACUGGUGAA 20 7466 BCL11A-5889 + CAAAUUUUCUCAGAACUUAA 20 7467 BCL11A-5890 + UGGUAUUCUUAGCAGGUUAA 20 7468 BCL11A-5891 - AUAGACGAUGGCACUGUUAA 20 7469 BCL11A-5892 + UCUCGGUGGUGGACUAAACA 20 7470 BCL11A-5893 - CCCGGCCGCGAUGCCCAACA 20 7471 BCL11A-5894 - AUCUACUUAGAAAGCGAACA 20 7472 BCL11A-5895 - GGUGCACCGGCGCAGCCACA 20 7473 BCL11A-3377 - GGCCGAGGCCGAGGGCCACA 20 7474 BCL11A-5896 - UCACCCGAGUGCCUUUGACA 20 7475 BCL11A-5897 + GCUCUUGAACUUGGCCACCA 20 7476 BCL11A-5898 - GAGAAAAUUUGAAGCCCCCA 20 7477 BCL11A-5899 + UGUCUGCAAUAUGAAUCCCA 20 7478 BCL11A-5900 - GGCUAUGGAGCCUCCCGCCA 20 7479 BCL11A-5901 + ACUCGGGUGAUGGGUGGCCA 20 7480 BCL11A-5902 + AAGUCUCCUAGAGAAAUCCA 20 7481 BCL11A-5903 - CCUUCCCAGCCACCUCUCCA 20 7482 BCL11A-5904 - GAUCUCGGGGCGCAGCGGCA 20 7483 BCL11A-5905 - GCCCGACGUCAUGCAGGGCA 20 7484 BCL11A-5906 + GCCCUGCAUGACGUCGGGCA 20 7485 BCL11A-5907 - GGAGACUUAGAGAGCUGGCA 20 7486 BCL11A-5908 - GCCCUGCCCGACGUCAUGCA 20 7487 BCL11A-5909 + GGCCUCGCUGAAGUGCUGCA 20 7488 BCL11A-5910 - AACAGCCAUUCACCAGUGCA 20 7489 BCL11A-5911 - CAACACGCACAGAACACUCA 20 7490 BCL11A-5912 + GUCGUCGGACUUGACCGUCA 20 7491 BCL11A-5913 + GAUACCAACCCGCGGGGUCA 20 7492 BCL11A-5914 - GGCAGGCCCAGCUCAAAAGA 20 7493 BCL11A-5915 - GAGGCUUCCGGCCUGGCAGA 20 7494 BCL11A-5916 - GCGCCUGGGGGCGGAAGAGA 20 7495 BCL11A-5917 + GAGCUUGAUGCGCUUAGAGA 20 7496 BCL11A-5918 - GGAGCUGACGGAGAGCGAGA 20 7497 BCL11A-5919 - UAAGCGCAUCAAGCUCGAGA 20 7498 BCL11A-5920 - GAGUCGGACCGCAUAGACGA 20 7499 BCL11A-5921 - AUGACGGUCAAGUCCGACGA 20 7500 BCL11A-5922 - GGCCACCUGGCCGAGGCCGA 20 7501 BCL11A-5923 + GGAGUCUCCGAAGCUAAGGA 20 7502 BCL11A-5924 + GAGGGGGGGCGUCGCCAGGA 20 7503 BCL11A-5925 + AAGAGGUUGGAGACAGAGGA 20 7504 BCL11A-5926 + GAGGGGCGGAUUGCAGAGGA 20 7505 BCL11A-5927 + CCGGGGGCUGGGAGGGAGGA 20 7506 BCL11A-5928 - CGCCCGGGGAGCUGGACGGA 20 7507 BCL11A-5929 - GAUGUGUGGCAGUUUUCGGA 20 7508 BCL11A-5930 + GGCGGAUUGCAGAGGAGGGA 20 7509 BCL11A-5931 + GACUUGACCGGGGGCUGGGA 20 7510 BCL11A-5932 + CCAUGGAGAGGUGGCUGGGA 20 7511 BCL11A-5933 - ACACCGCCCGGGGAGCUGGA 20 7512 BCL11A-5934 - GCAGCGGCACGGGAAGUGGA 20 7513 BCL11A-5935 + CUCGCCCAGGACCUGGUGGA 20 7514 BCL11A-5936 - GCACAAAUCGUCCCCCAUGA 20 7515 BCL11A-5937 + CAUUCUGCACCUAGUCCUGA 20 7516 BCL11A-5938 - AGAGGAGGAGGAGGAGCUGA 20 7517 BCL11A-5939 + UGUCAAAGGCACUCGGGUGA 20 7518 BCL11A-5940 + CCGGGCCCGGACCACUAAUA 20 7519 BCL11A-5941 + GUUGCAGUAACCUUUGCAUA 20 7520 BCL11A-5942 - GAGAGCGAGAGGGUGGACUA 20 7521 BCL11A-5943 + GUCUGGAGUCUCCGAAGCUA 20 7522 BCL11A-5944 - GCGGUUGAAUCCAAUGGCUA 20 7523 BCL11A-5945 + UCGCACAGGUUGCACUUGUA 20 7524 BCL11A-5946 + UCAAAUUUUCUCAGAACUUA 20 7525 BCL11A-5947 + GUCUCGGUGGUGGACUAAAC 20 7526 BCL11A-5948 - CCAACCUGAUCCCGGAGAAC 20 7527 BCL11A-5949 - CGGAGCACUCCUCGGAGAAC 20 7528 BCL11A-5950 - GUGCACCGGCGCAGCCACAC 20 7529 BCL11A-5951 - UGGCCGAGGCCGAGGGCCAC 20 7530 BCL11A-5952 + GGGUGCACGCGUGGUCGCAC 20 7531 BCL11A-5953 - AUCUCGGGGCGCAGCGGCAC 20 7532 BCL11A-5954 + UUGCAAGAGAAACCAUGCAC 20 7533 BCL11A-5955 - AGAGCAACCUGGUGGUGCAC 20 7534 BCL11A-5956 + CCAGCAGCAGCUUUUUGGAC 20 7535 BCL11A-5957 + UCGCAUGACUUGGACUUGAC 20 7536 BCL11A-5958 - AUCACCCGAGUGCCUUUGAC 20 7537 BCL11A-5959 - GUUCAAAUUUCAGAGCAACC 20 7538 BCL11A-5960 - ACCGCCAGCUCCCCGGAACC 20 7539 BCL11A-5961 + GGCUGCGCCGGUGCACCACC 20 7540 BCL11A-5962 - GAAGCAUAAGCGCGGCCACC 20 7541 BCL11A-5963 - CUUCAGCGAGGCCUUCCACC 20 7542 BCL11A-5964 + UAUGCUUCUCGCCCAGGACC 20 7543 BCL11A-5965 + CGCAUGACUUGGACUUGACC 20 7544 BCL11A-5966 - UUUAACCUGCUAAGAAUACC 20 7545 BCL11A-5967 + AGGAAGGGCGGCUUGCUACC 20 7546 BCL11A-5968 - GUGCGACCACGCGUGCACCC 20 7547 BCL11A-5969 - UGAGAAAAUUUGAAGCCCCC 20 7548 BCL11A-5970 + GGGCCAUCUCUUCCGCCCCC 20 7549 BCL11A-5971 - CCCUCCUCCCUCCCAGCCCC 20 7550 BCL11A-5972 - GAAGGAGUUCGACCUGCCCC 20 7551 BCL11A-5973 + AUCCCUCCGUCCAGCUCCCC 20 7552 BCL11A-5974 - AAUGGCCGCGGCUGCUCCCC 20 7553 BCL11A-5975 - UCUAGCCCACCGCUGUCCCC 20 7554 BCL11A-5976 - UGCGCUUCUCCACACCGCCC 20 7555 BCL11A-5977 + CCCCCGAGGCCGACUCGCCC 20 7556 BCL11A-5978 + CGCGCUUAUGCUUCUCGCCC 20 7557 BCL11A-5979 - CAUAUUAGUGGUCCGGGCCC 20 7558 BCL11A-5980 - GGGGGCGGAAGAGAUGGCCC 20 7559 BCL11A-5981 + CUUUUGAGCUGGGCCUGCCC 20 7560 BCL11A-5982 - UCUCUCCACCGCCAGCUCCC 20 7561 BCL11A-5983 + GAUCCCUCCGUCCAGCUCCC 20 7562 BCL11A-5984 - UAAUGGCCGCGGCUGCUCCC 20 7563 BCL11A-5985 - UUACUGCAACCAUUCCAGCC 20 7564 BCL11A-5986 - CUACGGCUUCGGGCUGAGCC 20 7565 BCL11A-5987 - UUGCGCUUCUCCACACCGCC 20 7566 BCL11A-5988 - CCCCCACCGCAUAGAGCGCC 20 7567 BCL11A-5989 + CCCCCCGAGGCCGACUCGCC 20 7568 BCL11A-5990 + GAGGGAGGGGGGGCGUCGCC 20 7569 BCL11A-5991 + UGCAUAGGGCUGGGCCGGCC 20 7570 BCL11A-5992 - AUCGAGAGAGGCUUCCGGCC 20 7571 BCL11A-5993 + CCGUGUUGGGCAUCGCGGCC 20 7572 BCL11A-5994 + UGUGGCCCUCGGCCUCGGCC 20 7573 BCL11A-5995 + GAGCUGGGCCUGCCCGGGCC 20 7574 BCL11A-5996 - CCAUAUUAGUGGUCCGGGCC 20 7575 BCL11A-5997 + GGCGCUUCAGCUUGCUGGCC 20 7576 BCL11A-5998 + CACUCGGGUGAUGGGUGGCC 20 7577 BCL11A-5999 + UCUUUUGAGCUGGGCCUGCC 20 7578 BCL11A-6000 + GAAGGGAUCUUUGAGCUGCC 20 7579 BCL11A-6001 + GUGGAAAGCGCCCUUCUGCC 20 7580 BCL11A-6002 + CCCACCAAGUCGCUGGUGCC 20 7581 BCL11A-6003 + GCCUCUCUCGAUACUGAUCC 20 7582 BCL11A-6004 - GAACGACCCCAACCUGAUCC 20 7583 BCL11A-6005 + CGUGGUGGCGCGCCGCCUCC 20 7584 BCL11A-6006 - UCGCCGGCUACGCGGCCUCC 20 7585 BCL11A-6007 + CCUCCUCGUCCCCGUUCUCC 20 7586 BCL11A-6008 - CGAGGCCUUCCACCAGGUCC 20 7587 BCL11A-6009 - ACGCCCCAUAUUAGUGGUCC 20 7588 BCL11A-6010 - AGGUAGCAAGCCGCCCUUCC 20 7589 BCL11A-6011 + AGUCGCUGGUGCCGGGUUCC 20 7590 BCL11A-6012 - CUCUAGGAGACUUAGAGAGC 20 7591 BCL11A-6013 + AGAGAAGGGGCUCAGCGAGC 20 7592 BCL11A-6014 - CUCCACACCGCCCGGGGAGC 20 7593 BCL11A-6015 + GGUGCCGGGUUCCGGGGAGC 20 7594 BCL11A-6016 + GCGUCUGCCCUCUUUUGAGC 20 7595 BCL11A-6017 + CUGCCUGGAGGCCGCGUAGC 20 7596 BCL11A-6018 + CUGAUCCUGGUAUUCUUAGC 20 7597 BCL11A-6019 + CUGAAGGGAUACCAACCCGC 20 7598 BCL11A-6020 - CGGAAGUCCCCUGACCCCGC 20 7599 BCL11A-6021 + UCUCGCCCGUGUGGCUGCGC 20 7600 BCL11A-6022 + GUCUAUGCGGUCCGACUCGC 20 7601 BCL11A-6023 - CCACCACGAGAACAGCUCGC 20 7602 BCL11A-6024 - GUGUACUCGCAGUGGCUCGC 20 7603 BCL11A-6025 + GGCGCUGCCCACCAAGUCGC 20 7604 BCL11A-6026 - GCCCACCGCUGUCCCCAGGC 20 7605 BCL11A-6027 + AAAGCGCCCUUCUGCCAGGC 20 7606 BCL11A-6028 + UCCGUGUUGGGCAUCGCGGC 20 7607 BCL11A-6029 + CAGUAACCUUUGCAUAGGGC 20 7608 BCL11A-6030 - UUAGUGGUCCGGGCCCGGGC 20 7609 BCL11A-6031 + UGCCCUGCAUGACGUCGGGC 20 7610 BCL11A-6032 + ACUUGGACUUGACCGGGGGC 20 7611 BCL11A-6033 + UGGGCAUCGCGGCCGGGGGC 20 7612 BCL11A-6034 + ACCUUUGCAUAGGGCUGGGC 20 7613 BCL11A-6035 + CUCCUAGAGAAAUCCAUGGC 20 7614 BCL11A-6036 + AGGGCGGCUUGCUACCUGGC 20 7615 BCL11A-6037 - AGGAGACUUAGAGAGCUGGC 20 7616 BCL11A-6038 + GAAUCCCAUGGAGAGGUGGC 20 7617 BCL11A-6039 - UGCGACGAAGACUCGGUGGC 20 7618 BCL11A-6040 - CGCCCUGCCCGACGUCAUGC 20 7619 BCL11A-5467 + AGUUGUACAUGUGUAGCUGC 20 7620 BCL11A-6041 + CACGGACUUGAGCGCGCUGC 20 7621 BCL11A-6042 - CCUGUCCAAAAAGCUGCUGC 20 7622 BCL11A-6043 + GCCCACCAAGUCGCUGGUGC 20 7623 BCL11A-6044 + CAUGUGGCGCUUCAGCUUGC 20 7624 BCL11A-6045 + CGUCCCCGUUCUCCGGGAUC 20 7625 BCL11A-6046 + GCACCCUGUCAAAGGCACUC 20 7626 BCL11A-6047 - UCCCCGGGCGAGUCGGCCUC 20 7627 BCL11A-6048 - GAGCUGGACGGAGGGAUCUC 20 7628 BCL11A-6049 + GCCACACAUCUUGAGCUCUC 20 7629 BCL11A-6050 + UCCUCCUCGUCCCCGUUCUC 20 7630 BCL11A-6051 + ACCAUGCCCUGCAUGACGUC 20 7631 BCL11A-6052 + GGAUACCAACCCGCGGGGUC 20 7632 BCL11A-6053 - CACGCCCCAUAUUAGUGGUC 20 7633 BCL11A-6054 + GGAGGCAAAAGGCGAUUGUC 20 7634 BCL11A-6055 - CCGCGGGUUGGUAUCCCUUC 20 7635 BCL11A-6056 - UCAGUAUCGAGAGAGGCUUC 20 7636 BCL11A-6057 - AGAGGGUGGACUACGGCUUC 20 7637 BCL11A-6058 + AAGUCGCUGGUGCCGGGUUC 20 7638 BCL11A-6059 - GGGCAGGCCCAGCUCAAAAG 20 7639 BCL11A-6060 + UGUGUGAAGAACCUAGAAAG 20 7640 BCL11A-6061 + GUAUUCUUAGCAGGUUAAAG 20 7641 BCL11A-3449 - CGACGAGGAAGAGGAAGAAG 20 7642 BCL11A-6062 + GCUUGAUGCGCUUAGAGAAG 20 7643 BCL11A-3448 - AGAGGAGGACGACGAGGAAG 20 7644 BCL11A-3453 - AGAGGAAGAAGAGGAGGAAG 20 7645 BCL11A-3441 - GAACGGGGACGAGGAGGAAG 20 7646 BCL11A-3376 - GGGCGCAGCGGCACGGGAAG 20 7647 BCL11A-6063 + CUCGGUGGUGGACUAAACAG 20 7648 BCL11A-6064 + UAGAAAGAGGUUGGAGACAG 20 7649 BCL11A-6065 + CUGGGCCGGCCUGGGGACAG 20 7650 BCL11A-6066 - AGAAAAUUUGAAGCCCCCAG 20 7651 BCL11A-6067 - GGAGGGAUCUCGGGGCGCAG 20 7652 BCL11A-6068 - CGGAGAACGUGUACUCGCAG 20 7653 BCL11A-6069 + GGAGGAGGGGCGGAUUGCAG 20 7654 BCL11A-6070 + AUACCAACCCGCGGGGUCAG 20 7655 BCL11A-6071 - ACCAGGAUCAGUAUCGAGAG 20 7656 BCL11A-6072 - AGGAGCUGACGGAGAGCGAG 20 7657 BCL11A-6073 + AGAGGUUGGAGACAGAGGAG 20 7658 BCL11A-6074 + CGGGGGCUGGGAGGGAGGAG 20 7659 BCL11A-6075 + GCGGAUUGCAGAGGAGGGAG 20 7660 BCL11A-6076 + UGGACUAAACAGGGGGGGAG 20 7661 BCL11A-6077 + GCAAUAUGAAUCCCAUGGAG 20 7662 BCL11A-6078 - GGGAGCACGCCCCAUAUUAG 20 7663 BCL11A-6079 - CAACCUGAUCCCGGAGAACG 20 7664 BCL11A-3450 - GGAGGAAGAGGAGGACGACG 20 7665 BCL11A-6080 + CUCCGAGGAGUGCUCCGACG 20 7666 BCL11A-6081 - GAUCCCGGAGAACGGGGACG 20 7667 BCL11A-6082 - GCAGUGGCUCGCCGGCUACG 20 7668 BCL11A-6083 + GCAUGACUUGGACUUGACCG 20 7669 BCL11A-6084 + CCUGAAGGGAUACCAACCCG 20 7670 BCL11A-6085 - ACGGAAGUCCCCUGACCCCG 20 7671 BCL11A-6086 + CUUUUUGGACAGGCCCCCCG 20 7672 BCL11A-6087 - GCGCUUCUCCACACCGCCCG 20 7673 BCL11A-6088 + CCCCGAGGCCGACUCGCCCG 20 7674 BCL11A-6089 + ACUCGCCCGGGGAGCAGCCG 20 7675 BCL11A-6090 - CGGCCACCUGGCCGAGGCCG 20 7676 BCL11A-6091 + CGUGUUGGGCAUCGCGGCCG 20 7677 BCL11A-6092 - GAUGGCACUGUUAAUGGCCG 20 7678 BCL11A-6093 - UAAGCGCGGCCACCUGGCCG 20 7679 BCL11A-6094 + GCGCAAACUCCCGUUCUCCG 20 7680 BCL11A-6095 - CAGCAGCGCGCUCAAGUCCG 20 7681 BCL11A-6096 + GUCGCUGGUGCCGGGUUCCG 20 7682 BCL11A-6097 - CUGGGCGAGAAGCAUAAGCG 20 7683 BCL11A-6098 - CUCCAUGCAGCACUUCAGCG 20 7684 BCL11A-6099 + UGCUGGCCUGGGUGCACGCG 20 7685 BCL11A-6100 + UGAAGGGAUACCAACCCGCG 20 7686 BCL11A-6101 - CACCACGAGAACAGCUCGCG 20 7687 BCL11A-6102 + GCAUGACGUCGGGCAGGGCG 20 7688 BCL11A-6103 - CGAGAACAGCUCGCGGGGCG 20 7689 BCL11A-6104 - GCGGGGCGCGGUCGUGGGCG 20 7690 BCL11A-6105 + GUUCUCCGUGUUGGGCAUCG 20 7691 BCL11A-6106 - CCCCGGGCGAGUCGGCCUCG 20 7692 BCL11A-6107 - GCCACCACGAGAACAGCUCG 20 7693 BCL11A-6108 - AGCUGGACGGAGGGAUCUCG 20 7694 BCL11A-6109 + CGCCCCGCGAGCUGUUCUCG 20 7695 BCL11A-6110 - CAGCUCGCGGGGCGCGGUCG 20 7696 BCL11A-6111 + UCGGUGGUGGACUAAACAGG 20 7697 BCL11A-6112 + GGCCCUCGGCCUCGGCCAGG 20 7698 BCL11A-3451 - CGAGGAAGAGGAAGAAGAGG 20 7699 BCL11A-3452 - GGAAGAAGAGGAGGAAGAGG 20 7700 BCL11A-3445 - CGGGGACGAGGAGGAAGAGG 20 7701 BCL11A-6113 + AAAGAGGUUGGAGACAGAGG 20 7702 BCL11A-6114 + GGAGGGGCGGAUUGCAGAGG 20 7703 BCL11A-6115 + AUAUGAAUCCCAUGGAGAGG 20 7704 BCL11A-6116 + CGAGGAGUGCUCCGACGAGG 20 7705 BCL11A-3330 - CCCGGAGAACGGGGACGAGG 20 7706 BCL11A-3454 - AGAAGAGGAGGAAGAGGAGG 20 7707 BCL11A-6117 + GAGGUUGGAGACAGAGGAGG 20 7708 BCL11A-3455 - AGAGGAGGAAGAGGAGGAGG 20 7709 BCL11A-6118 + CGGAUUGCAGAGGAGGGAGG 20 7710 BCL11A-6119 + ACCGGGGGCUGGGAGGGAGG 20 7711 BCL11A-6120 - CUUCGGGCUGAGCCUGGAGG 20 7712 BCL11A-6121 - CCGCCCGGGGAGCUGGACGG 20 7713 BCL11A-6122 + CAUGACUUGGACUUGACCGG 20 7714 BCL11A-6123 + GUGUUGGGCAUCGCGGCCGG 20 7715 BCL11A-6124 + GGCCGGCCUGGGGACAGCGG 20 7716 BCL11A-6125 + GGGUUCCGGGGAGCUGGCGG 20 7717 BCL11A-6126 + CCCCCAGGCGCUCUAUGCGG 20 7718 BCL11A-6127 - CACUUGCGACGAAGACUCGG 20 7719 BCL11A-6128 - CCCGGGCGAGUCGGCCUCGG 20 7720 BCL11A-6129 + GGGUCCAAGUGAUGUCUCGG 20 7721 BCL11A-6130 + GGGGGCGUCGCCAGGAAGGG 20 7722 BCL11A-6131 + CGGUGGUGGACUAAACAGGG 20 7723 BCL11A-6132 - GCUGACGGAGAGCGAGAGGG 20 7724 BCL11A-6133 + GGGCGGAUUGCAGAGGAGGG 20 7725 BCL11A-6134 + GGAUUGCAGAGGAGGGAGGG 20 7726 BCL11A-6135 + UUGACCGGGGGCUGGGAGGG 20 7727 BCL11A-6136 + CCUCCGUCCAGCUCCCCGGG 20 7728 BCL11A-6137 + CUAGAGAAAUCCAUGGCGGG 20 7729 BCL11A-6138 - CCGGGCGAGUCGGCCUCGGG 20 7730 BCL11A-6139 + GGUGGUGGACUAAACAGGGG 20 7731 BCL11A-6140 - AAAUUUGAAGCCCCCAGGGG 20 7732 BCL11A-6141 + GGGCUGGGAGGGAGGAGGGG 20 7733 BCL11A-6142 + GAUUGCAGAGGAGGGAGGGG 20 7734 BCL11A-6143 - CCGCAUAGAGCGCCUGGGGG 20 7735 BCL11A-6144 - UGAAGCCCCCAGGGGUGGGG 20 7736 BCL11A-6145 + AAAGGCACUCGGGUGAUGGG 20 7737 BCL11A-6146 + GGACUUGACCGGGGGCUGGG 20 7738 BCL11A-6147 + CUAAACAGGGGGGGAGUGGG 20 7739 BCL11A-6148 + CUGGGUACUACGCCGAAUGG 20 7740 BCL11A-6149 + UCUCCUAGAGAAAUCCAUGG 20 7741 BCL11A-6150 + GUCGGACUUGACCGUCAUGG 20 7742 BCL11A-6151 - CAAAUUUCAGAGCAACCUGG 20 7743 BCL11A-6152 + GCUUCUCGCCCAGGACCUGG 20 7744 BCL11A-6153 - CGGCUUCGGGCUGAGCCUGG 20 7745 BCL11A-6154 - CCACCGCAUAGAGCGCCUGG 20 7746 BCL11A-6155 + GGGAUCUUUGAGCUGCCUGG 20 7747 BCL11A-6156 + GCCGGGUUCCGGGGAGCUGG 20 7748 BCL11A-6157 - CGCAGCGGCACGGGAAGUGG 20 7749 BCL11A-6158 - CAGCGCGCUCAAGUCCGUGG 20 7750 BCL11A-6159 + CCCGCGAGCUGUUCUCGUGG 20 7751 BCL11A-6160 + CCAGGCGCUCUAUGCGGUGG 20 7752 BCL11A-6161 + UCCAAGUGAUGUCUCGGUGG 20 7753 BCL11A-6162 - ACCCGGCACCAGCGACUUGG 20 7754 BCL11A-6163 + UCUGGGUACUACGCCGAAUG 20 7755 BCL11A-6164 + CGUCGGACUUGACCGUCAUG 20 7756 BCL11A-6165 + UGUGCAUGUGCGUCUUCAUG 20 7757 BCL11A-6166 + GGGCCCGGACCACUAAUAUG 20 7758 BCL11A-6167 + CCGCCCCCAGGCGCUCUAUG 20 7759 BCL11A-6168 + UAACAGUGCCAUCGUCUAUG 20 7760 BCL11A-6169 - AGCGACACUUGUGAGUACUG 20 7761 BCL11A-6170 + CUUCGUCGCAAGUGUCCCUG 20 7762 BCL11A-6171 - CCCACCGCAUAGAGCGCCUG 20 7763 BCL11A-6172 + CAUAGGGCUGGGCCGGCCUG 20 7764 BCL11A-6173 + AGAAGGGGCUCAGCGAGCUG 20 7765 BCL11A-6174 - GUGCCUUUGACAGGGUGCUG 20 7766 BCL11A-6175 - UCCAAGUCAUGCGAGUUCUG 20 7767 BCL11A-6176 + UGUAGGGCUUCUCGCCCGUG 20 7768 BCL11A-6177 + GUCCAGCUCCCCGGGCGGUG 20 7769 BCL11A-6178 + CCCAGGCGCUCUAUGCGGUG 20 7770 BCL11A-6179 - AUUUGAAGCCCCCAGGGGUG 20 7771 BCL11A-6180 - CCCAGAGAGCUCAAGAUGUG 20 7772 BCL11A-6181 + CGUUCUCCGGGAUCAGGUUG 20 7773 BCL11A-6182 + CUCUGGGUACUACGCCGAAU 20 7774 BCL11A-6183 + GCGGGAGGCUCCAUAGCCAU 20 7775 BCL11A-6184 - CUUCCCAGCCACCUCUCCAU 20 7776 BCL11A-6185 + GGUUGCAGUAACCUUUGCAU 20 7777 BCL11A-6186 + UCGUCGGACUUGACCGUCAU 20 7778 BCL11A-6187 + GUCAAAGGCACUCGGGUGAU 20 7779 BCL11A-6188 + CGGGCCCGGACCACUAAUAU 20 7780 BCL11A-6189 + GUCGUUCUCGCUCUUGAACU 20 7781 BCL11A-6190 + AGCACCCUGUCAAAGGCACU 20 7782 BCL11A-6191 - UCCACCACCGAGACAUCACU 20 7783 BCL11A-6192 - GGACACUUGCGACGAAGACU 20 7784 BCL11A-6193 - GGAACCCGGCACCAGCGACU 20 7785 BCL11A-6194 - GUUGGUAUCCCUUCAGGACU 20 7786 BCL11A-6195 + GCCGCAGAACUCGCAUGACU 20 7787 BCL11A-6196 + GCAAGUGUCCCUGUGGCCCU 20 7788 BCL11A-6197 - CCCCACCGCAUAGAGCGCCU 20 7789 BCL11A-6198 + GCAUAGGGCUGGGCCGGCCU 20 7790 BCL11A-6199 + GUCCCUGUGGCCCUCGGCCU 20 7791 BCL11A-6200 - CUCCCCGGGCGAGUCGGCCU 20 7792 BCL11A-6201 + GCGCUUCAGCUUGCUGGCCU 20 7793 BCL11A-6202 - CUCCUCGUCGGAGCACUCCU 20 7794 BCL11A-6203 - GAGGCCUUCCACCAGGUCCU 20 7795 BCL11A-6204 + GAGAAGGGGCUCAGCGAGCU 20 7796 BCL11A-6205 + CGUCUGCCCUCUUUUGAGCU 20 7797 BCL11A-6206 + AGUAACCUUUGCAUAGGGCU 20 7798 BCL11A-6207 + CUUGGACUUGACCGGGGGCU 20 7799 BCL11A-6208 + AAUCCCAUGGAGAGGUGGCU 20 7800 BCL11A-5508 + GUUGUACAUGUGUAGCUGCU 20 7801 BCL11A-6209 - CUGUCCAAAAAGCUGCUGCU 20 7802 BCL11A-6210 - GGAGCUGGACGGAGGGAUCU 20 7803 BCL11A-6211 + CCACACAUCUUGAGCUCUCU 20 7804 BCL11A-6212 - CUCCCGCCAUGGAUUUCUCU 20 7805 BCL11A-6213 + UGGGGGUCCAAGUGAUGUCU 20 7806 BCL11A-6214 - UCUGUCUCCAACCUCUUUCU 20 7807 BCL11A-6215 - AGACUCGGUGGCCGGCGAGU 20 7808 BCL11A-6216 - CGGCUGCUCCCCGGGCGAGU 20 7809 BCL11A-6217 + GGACUAAACAGGGGGGGAGU 20 7810 BCL11A-6218 + CACCAUGCCCUGCAUGACGU 20 7811 BCL11A-6219 - CGGGGCGCGGUCGUGGGCGU 20 7812 BCL11A-6220 - AUCGCCUUUUGCCUCCUCGU 20 7813 BCL11A-6221 + GGCGGUGGAGAGACCGUCGU 20 7814 BCL11A-6222 - AGCUCGCGGGGCGCGGUCGU 20 7815 BCL11A-6223 + CCCGUUCUCCGGGAUCAGGU 20 7816 BCL11A-6224 + UGAAGAACCUAGAAAGAGGU 20 7817 BCL11A-6225 + GCCGGCCUGGGGACAGCGGU 20 7818 BCL11A-6226 + CCCCAGGCGCUCUAUGCGGU 20 7819 BCL11A-6227 - AGUCCCCUGACCCCGCGGGU 20 7820 BCL11A-6228 - AAUUUGAAGCCCCCAGGGGU 20 7821 BCL11A-6229 - CCCGGCACCAGCGACUUGGU 20 7822 BCL11A-6230 - GCGACACUUGUGAGUACUGU 20 7823 BCL11A-6231 + CGAGUACACGUUCUCCGUGU 20 7824 BCL11A-6232 + GUCGCACAGGUUGCACUUGU 20 7825 BCL11A-6233 - GUUCUUCACACACCCCCAUU 20 7826 BCL11A-6234 - AAAGAUCCCUUCCUUAGCUU 20 7827 BCL11A-6235 - GAGAGGGUGGACUACGGCUU 20 7828 BCL11A-6236 + CCGUUCUCCGGGAUCAGGUU 20 7829 BCL11A-6237 + GAGUACACGUUCUCCGUGUU 20 7830 BCL11A-6238 + GCUGCCCAGCAGCAGCUUUU 20 7831 BCL11A-6239 - UCAAGAUGUGUGGCAGUUUU 20 7832

Table 15D provides targeting domains for knocking out the BCL11A gene by dual targeting (e.g., dual single strand cleavages). In an embodiment, dual targeting (e.g., dual nicking) is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. Exemplary nickase pairs include a targeting domain from Group A and a second targeting domain from Group B, or include a targeting domain from Group C and a second targeting domain from Group D. It is contemplated herein that in an embodiment a targeting domain of Group A can be combined with any of the targeting domains of Group B; in an embodiment a targeting domain of Group C can be combined with any of the targeting domains of Group D. Exemplary gRNA pairs to be used with S. pyogenes Cas9 are shown in Table 151D, e.g., BCL11A-5355 or BCL11A-5380 can be combined with BCL11A-5321 or BCL11A-5416; or BCL11A-5333, BCL11A-5354, or BCL11A-5329 can be combined with BCL11A-5367 or BCL11A-5341.

TABLE 15D Group A Group B BCL11A-5355, BCL11A-5321, BCL11A-5380 BCL11A-5416 Group C Group D BCL11A-5333, BCL11A- BCL11A-5367, 5354, BCL11A-5329 BCL11A-5341

Table 16A provides exemplary targeting domains for knocking out the BCL11A gene selected according to the first tier parameters. The targeting domains bind within the first 500 bp of the coding sequence (e.g., within 500 bp downstream from the start codon) and have a high level of orthogonality, and the PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 16A 1st Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-6240 + UGACCUGGAUGCCAACCUCCA 21 7833 BCL11A-6241 + GUGACCUGGAUGCCAACCUCCA 22 7834 BCL11A-6242 + CGUGACCUGGAUGCCAACCUCCA 23 7835 BCL11A-6243 + GCGUGACCUGGAUGCCAACCUCCA 24 7836 BCL11A-6244 + AUGCCAACCUCCACGGGA 18 7837 BCL11A-6245 + GAUGCCAACCUCCACGGGA 19 7838 BCL11A-6246 + GGAUGCCAACCUCCACGGGA 20 7839 BCL11A-6247 + UGGAUGCCAACCUCCACGGGA 21 7840 BCL11A-6248 + CUGGAUGCCAACCUCCACGGGA 22 7841 BCL11A-6249 + CCUGGAUGCCAACCUCCACGGGA 23 7842 BCL11A-6250 + ACCUGGAUGCCAACCUCCACGGGA 24 7843 BCL11A-6251 + GUCAUCCUCUGGCGUGAC 18 7844 BCL11A-6252 + CGUCAUCCUCUGGCGUGAC 19 7845 BCL11A-6253 + UCGUCAUCCUCUGGCGUGAC 20 7846 BCL11A-6254 + AUCGUCAUCCUCUGGCGUGAC 21 7847 BCL11A-6255 + AAUCGUCAUCCUCUGGCGUGAC 22 7848 BCL11A-6256 + CAAUCGUCAUCCUCUGGCGUGAC 23 7849 BCL11A-6257 + ACAAUCGUCAUCCUCUGGCGUGAC 24 7850 BCL11A-6258 + UUAUUGGGUUACUUACGC 18 7851 BCL11A-6259 + AUUAUUGGGUUACUUACGC 19 7852 BCL11A-6260 + UAUUAUUGGGUUACUUACGC 20 7853 BCL11A-6261 + CUAUUAUUGGGUUACUUACGC 21 7854 BCL11A-6262 + ACUAUUAUUGGGUUACUUACGC 22 7855 BCL11A-6263 + UACUAUUAUUGGGUUACUUACGC 23 7856 BCL11A-6264 + UUACUAUUAUUGGGUUACUUACGC 24 7857 BCL11A-6265 + UCCCGUUUGCUUAAGUGC 18 7858 BCL11A-6266 + UUCCCGUUUGCUUAAGUGC 19 7859 BCL11A-5352 + AUUCCCGUUUGCUUAAGUGC 20 7860 BCL11A-6267 + AAUUCCCGUUUGCUUAAGUGC 21 7861 BCL11A-6268 + GAAUUCCCGUUUGCUUAAGUGC 22 7862 BCL11A-6269 + AGAAUUCCCGUUUGCUUAAGUGC 23 7863 BCL11A-6270 + GAGAAUUCCCGUUUGCUUAAGUGC 24 7864 BCL11A-6271 + UUUGUGCUCGAUAAAAAU 18 7865 BCL11A-6272 + GUUUGUGCUCGAUAAAAAU 19 7866 BCL11A-6273 + CGUUUGUGCUCGAUAAAAAU 20 7867 BCL11A-6274 + CCGUUUGUGCUCGAUAAAAAU 21 7868 BCL11A-6275 + UCCGUUUGUGCUCGAUAAAAAU 22 7869 BCL11A-6276 + UUCCGUUUGUGCUCGAUAAAAAU 23 7870 BCL11A-6277 + UUUCCGUUUGUGCUCGAUAAAAAU 24 7871 BCL11A-6278 + UGCACUCAUCCCAGGCGU 18 7872 BCL11A-6279 + CUGCACUCAUCCCAGGCGU 19 7873 BCL11A-5510 + UCUGCACUCAUCCCAGGCGU 20 7874 BCL11A-6280 + UUCUGCACUCAUCCCAGGCGU 21 7875 BCL11A-6281 + AUUCUGCACUCAUCCCAGGCGU 22 7876 BCL11A-6282 + UAUUCUGCACUCAUCCCAGGCGU 23 7877 BCL11A-6283 + AUAUUCUGCACUCAUCCCAGGCGU 24 7878 BCL11A-6284 + GUCUGGUUCAUCAUCUGU 18 7879 BCL11A-6285 + GGUCUGGUUCAUCAUCUGU 19 7880 BCL11A-6286 + UGGUCUGGUUCAUCAUCUGU 20 7881 BCL11A-6287 + GUGGUCUGGUUCAUCAUCUGU 21 7882 BCL11A-6288 + CGUGGUCUGGUUCAUCAUCUGU 22 7883 BCL11A-6289 + CCGUGGUCUGGUUCAUCAUCUGU 23 7884 BCL11A-6290 + GCCGUGGUCUGGUUCAUCAUCUGU 24 7885 BCL11A-6291 - CCGUUGGGAGCUCCAGAA 18 7886 BCL11A-6292 - CCCGUUGGGAGCUCCAGAA 19 7887 BCL11A-5447 - GCCCGUUGGGAGCUCCAGAA 20 7888 BCL11A-6293 - GGCCCGUUGGGAGCUCCAGAA 21 7889 BCL11A-6294 - CGGCCCGUUGGGAGCUCCAGAA 22 7890 BCL11A-6295 - ACGGCCCGUUGGGAGCUCCAGAA 23 7891 BCL11A-6296 - CACGGCCCGUUGGGAGCUCCAGAA 24 7892 BCL11A-6297 - GGCAUCCAGGUCACGCCA 18 7893 BCL11A-6298 - UGGCAUCCAGGUCACGCCA 19 7894 BCL11A-6299 - UUGGCAUCCAGGUCACGCCA 20 7895 BCL11A-6300 - GUUGGCAUCCAGGUCACGCCA 21 7896 BCL11A-6301 - GGUUGGCAUCCAGGUCACGCCA 22 7897 BCL11A-6302 - AGGUUGGCAUCCAGGUCACGCCA 23 7898 BCL11A-6303 - GAGGUUGGCAUCCAGGUCACGCCA 24 7899 BCL11A-6304 - AACCCCAGCACUUAAGCAAAC 21 7900 BCL11A-6305 - AAACCCCAGCACUUAAGCAAAC 22 7901 BCL11A-6306 - CAAACCCCAGCACUUAAGCAAAC 23 7902 BCL11A-6307 - GCAAACCCCAGCACUUAAGCAAAC 24 7903 BCL11A-6308 - AGCUCUAAUCCCCACGCC 18 7904 BCL11A-6309 - GAGCUCUAAUCCCCACGCC 19 7905 BCL11A-5350 - GGAGCUCUAAUCCCCACGCC 20 7906 BCL11A-6310 - UGGAGCUCUAAUCCCCACGCC 21 7907 BCL11A-6311 - AUGGAGCUCUAAUCCCCACGCC 22 7908 BCL11A-6312 - CAUGGAGCUCUAAUCCCCACGCC 23 7909 BCL11A-6313 - ACAUGGAGCUCUAAUCCCCACGCC 24 7910 BCL11A-6314 - UUUAUCAACGUCAUCUAG 18 7911 BCL11A-6315 - GUUUAUCAACGUCAUCUAG 19 7912 BCL11A-5356 - UGUUUAUCAACGUCAUCUAG 20 7913 BCL11A-6316 - UUGUUUAUCAACGUCAUCUAG 21 7914 BCL11A-6317 - AUUGUUUAUCAACGUCAUCUAG 22 7915 BCL11A-6318 - GAUUGUUUAUCAACGUCAUCUAG 23 7916 BCL11A-6319 - CGAUUGUUUAUCAACGUCAUCUAG 24 7917 BCL11A-6320 - AGUGCAGAAUAUGCCCCG 18 7918 BCL11A-6321 - GAGUGCAGAAUAUGCCCCG 19 7919 BCL11A-6322 - UGAGUGCAGAAUAUGCCCCG 20 7920 BCL11A-6323 - AUGAGUGCAGAAUAUGCCCCG 21 7921 BCL11A-6324 - GAUGAGUGCAGAAUAUGCCCCG 22 7922 BCL11A-6325 - GGAUGAGUGCAGAAUAUGCCCCG 23 7923 BCL11A-6326 - GGGAUGAGUGCAGAAUAUGCCCCG 24 7924 BCL11A-6327 - CUAAUCCCCACGCCUGGG 18 7925 BCL11A-6328 - UCUAAUCCCCACGCCUGGG 19 7926 BCL11A-6329 - CUCUAAUCCCCACGCCUGGG 20 7927 BCL11A-6330 - GCUCUAAUCCCCACGCCUGGG 21 7928 BCL11A-6331 - AGCUCUAAUCCCCACGCCUGGG 22 7929 BCL11A-6332 - GAGCUCUAAUCCCCACGCCUGGG 23 7930 BCL11A-6333 - GGAGCUCUAAUCCCCACGCCUGGG 24 7931 BCL11A-6334 - CCACGCCUGGGAUGAGUG 18 7932 BCL11A-6335 - CCCACGCCUGGGAUGAGUG 19 7933 BCL11A-6336 - CCCCACGCCUGGGAUGAGUG 20 7934 BCL11A-6337 - UCCCCACGCCUGGGAUGAGUG 21 7935 BCL11A-6338 - AUCCCCACGCCUGGGAUGAGUG 22 7936 BCL11A-6339 - AAUCCCCACGCCUGGGAUGAGUG 23 7937 BCL11A-6340 - UAAUCCCCACGCCUGGGAUGAGUG 24 7938 BCL11A-6341 - CUCUGCUUAGAAAAAGCU 18 7939 BCL11A-6342 - CCUCUGCUUAGAAAAAGCU 19 7940 BCL11A-6343 - GCCUCUGCUUAGAAAAAGCU 20 7941 BCL11A-6344 - AGCCUCUGCUUAGAAAAAGCU 21 7942 BCL11A-6345 - CAGCCUCUGCUUAGAAAAAGCU 22 7943 BCL11A-6346 - GCAGCCUCUGCUUAGAAAAAGCU 23 7944 BCL11A-6347 - GGCAGCCUCUGCUUAGAAAAAGCU 24 7945

Table 16B provides exemplary targeting domains for knocking out the BCL11A gene selected according to the second tier parameters. The targeting domains bind within the first 500 bp of the coding sequence (e.g., within 500 bp downstream from the start codon), and the PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 16B 2nd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-6348 + CCUGGAUGCCAACCUCCA 18 7946 BCL11A-6349 + ACCUGGAUGCCAACCUCCA 19 7947 BCL11A-5450 + GACCUGGAUGCCAACCUCCA 20 7948 BCL11A-6350 - CCCAGCACUUAAGCAAAC 18 7949 BCL11A-6351 - CCCCAGCACUUAAGCAAAC 19 7950 BCL11A-5458 - ACCCCAGCACUUAAGCAAAC 20 7951

Table 16C provides exemplary targeting domains for knocking out the BCL11A gene selected according to the third tier parameters. The targeting domains bind within the first 500 bp of the coding sequence (e.g., within 500 bp downstream from the start codon), and the PAM is NNGRRV. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 16C 3rd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-6352 + AAUAAGAAUGUCCCCCAA 18 7952 BCL11A-6353 + AAAUAAGAAUGUCCCCCAA 19 7953 BCL11A-5444 + AAAAUAAGAAUGUCCCCCAA 20 7954 BCL11A-6354 + AAAAAUAAGAAUGUCCCCCAA 21 7955 BCL11A-6355 + UAAAAAUAAGAAUGUCCCCCAA 22 7956 BCL11A-6356 + AUAAAAAUAAGAAUGUCCCCCAA 23 7957 BCL11A-6357 + GAUAAAAAUAAGAAUGUCCCCCAA 24 7958 BCL11A-6358 + UUCAUCUCGAUUGGUGAA 18 7959 BCL11A-6359 + UUUCAUCUCGAUUGGUGAA 19 7960 BCL11A-5344 + UUUUCAUCUCGAUUGGUGAA 20 7961 BCL11A-6360 + UUUUUCAUCUCGAUUGGUGAA 21 7962 BCL11A-6361 + UUUUUUCAUCUCGAUUGGUGAA 22 7963 BCL11A-6362 + CUUUUUUCAUCUCGAUUGGUGAA 23 7964 BCL11A-6363 + GCUUUUUUCAUCUCGAUUGGUGAA 24 7965 BCL11A-6364 + AAAUAAGAAUGUCCCCCA 18 7966 BCL11A-6365 + AAAAUAAGAAUGUCCCCCA 19 7967 BCL11A-6366 + AAAAAUAAGAAUGUCCCCCA 20 7968 BCL11A-6367 + UAAAAAUAAGAAUGUCCCCCA 21 7969 BCL11A-6368 + AUAAAAAUAAGAAUGUCCCCCA 22 7970 BCL11A-6369 + GAUAAAAAUAAGAAUGUCCCCCA 23 7971 BCL11A-6370 + CGAUAAAAAUAAGAAUGUCCCCCA 24 7972 BCL11A-6371 + CCCCUUCUGGAGCUCCCA 18 7973 BCL11A-6372 + UCCCCUUCUGGAGCUCCCA 19 7974 BCL11A-6373 + AUCCCCUUCUGGAGCUCCCA 20 7975 BCL11A-6374 + GAUCCCCUUCUGGAGCUCCCA 21 7976 BCL11A-6375 + UGAUCCCCUUCUGGAGCUCCCA 22 7977 BCL11A-6376 + AUGAUCCCCUUCUGGAGCUCCCA 23 7978 BCL11A-6377 + CAUGAUCCCCUUCUGGAGCUCCCA 24 7979 BCL11A-6378 + UAGAGCUCCAUGUGCAGA 18 7980 BCL11A-6379 + UUAGAGCUCCAUGUGCAGA 19 7981 BCL11A-6380 + AUUAGAGCUCCAUGUGCAGA 20 7982 BCL11A-6381 + GAUUAGAGCUCCAUGUGCAGA 21 7983 BCL11A-6382 + GGAUUAGAGCUCCAUGUGCAGA 22 7984 BCL11A-6383 + GGGAUUAGAGCUCCAUGUGCAGA 23 7985 BCL11A-6384 + GGGGAUUAGAGCUCCAUGUGCAGA 24 7986 BCL11A-6385 + GCUCCAUGUGCAGAACGA 18 7987 BCL11A-6386 + AGCUCCAUGUGCAGAACGA 19 7988 BCL11A-5347 + GAGCUCCAUGUGCAGAACGA 20 7989 BCL11A-6387 + AGAGCUCCAUGUGCAGAACGA 21 7990 BCL11A-6388 + UAGAGCUCCAUGUGCAGAACGA 22 7991 BCL11A-6389 + UUAGAGCUCCAUGUGCAGAACGA 23 7992 BCL11A-6390 + AUUAGAGCUCCAUGUGCAGAACGA 24 7993 BCL11A-6391 + UUUCAUCUCGAUUGGUGA 18 7994 BCL11A-6392 + UUUUCAUCUCGAUUGGUGA 19 7995 BCL11A-5456 + UUUUUCAUCUCGAUUGGUGA 20 7996 BCL11A-6393 + UUUUUUCAUCUCGAUUGGUGA 21 7997 BCL11A-6394 + CUUUUUUCAUCUCGAUUGGUGA 22 7998 BCL11A-6395 + GCUUUUUUCAUCUCGAUUGGUGA 23 7999 BCL11A-6396 + UGCUUUUUUCAUCUCGAUUGGUGA 24 8000 BCL11A-6397 + GCAGAAGUUUAUCUGUGA 18 8001 BCL11A-6398 + UGCAGAAGUUUAUCUGUGA 19 8002 BCL11A-6399 + GUGCAGAAGUUUAUCUGUGA 20 8003 BCL11A-6400 + AGUGCAGAAGUUUAUCUGUGA 21 8004 BCL11A-6401 + CAGUGCAGAAGUUUAUCUGUGA 22 8005 BCL11A-6402 + CCAGUGCAGAAGUUUAUCUGUGA 23 8006 BCL11A-6403 + UCCAGUGCAGAAGUUUAUCUGUGA 24 8007 BCL11A-6404 + GAGCUCCAUGUGCAGAAC 18 8008 BCL11A-6405 + AGAGCUCCAUGUGCAGAAC 19 8009 BCL11A-6406 + UAGAGCUCCAUGUGCAGAAC 20 8010 BCL11A-6407 + UUAGAGCUCCAUGUGCAGAAC 21 8011 BCL11A-6408 + AUUAGAGCUCCAUGUGCAGAAC 22 8012 BCL11A-6409 + GAUUAGAGCUCCAUGUGCAGAAC 23 8013 BCL11A-6410 + GGAUUAGAGCUCCAUGUGCAGAAC 24 8014 BCL11A-6411 + UAUUAUUGGGUUACUUAC 18 8015 BCL11A-6412 + CUAUUAUUGGGUUACUUAC 19 8016 BCL11A-6413 + ACUAUUAUUGGGUUACUUAC 20 8017 BCL11A-6414 + UACUAUUAUUGGGUUACUUAC 21 8018 BCL11A-6415 + UUACUAUUAUUGGGUUACUUAC 22 8019 BCL11A-6416 + AUUACUAUUAUUGGGUUACUUAC 23 8020 BCL11A-6417 + UAUUACUAUUAUUGGGUUACUUAC 24 8021 BCL11A-6418 + ACCUGGAUGCCAACCUCC 18 8022 BCL11A-6419 + GACCUGGAUGCCAACCUCC 19 8023 BCL11A-6420 + UGACCUGGAUGCCAACCUCC 20 8024 BCL11A-6421 + GUGACCUGGAUGCCAACCUCC 21 8025 BCL11A-6422 + CGUGACCUGGAUGCCAACCUCC 22 8026 BCL11A-6423 + GCGUGACCUGGAUGCCAACCUCC 23 8027 BCL11A-6424 + GGCGUGACCUGGAUGCCAACCUCC 24 8028 BCL11A-6425 + UCUGCACUCAUCCCAGGC 18 8029 BCL11A-6426 + UUCUGCACUCAUCCCAGGC 19 8030 BCL11A-6427 + AUUCUGCACUCAUCCCAGGC 20 8031 BCL11A-6428 + UAUUCUGCACUCAUCCCAGGC 21 8032 BCL11A-6429 + AUAUUCUGCACUCAUCCCAGGC 22 8033 BCL11A-6430 + CAUAUUCUGCACUCAUCCCAGGC 23 8034 BCL11A-6431 + GCAUAUUCUGCACUCAUCCCAGGC 24 8035 BCL11A-6432 + GAGGUCAUGAUCCCCUUC 18 8036 BCL11A-6433 + GGAGGUCAUGAUCCCCUUC 19 8037 BCL11A-5471 + AGGAGGUCAUGAUCCCCUUC 20 8038 BCL11A-6434 + GAGGAGGUCAUGAUCCCCUUC 21 8039 BCL11A-6435 + UGAGGAGGUCAUGAUCCCCUUC 22 8040 BCL11A-6436 + GUGAGGAGGUCAUGAUCCCCUUC 23 8041 BCL11A-6437 + GGUGAGGAGGUCAUGAUCCCCUUC 24 8042 BCL11A-6438 + AUCUGUAAGAAUGGCUUC 18 8043 BCL11A-6439 + CAUCUGUAAGAAUGGCUUC 19 8044 BCL11A-6440 + UCAUCUGUAAGAAUGGCUUC 20 8045 BCL11A-6441 + AUCAUCUGUAAGAAUGGCUUC 21 8046 BCL11A-6442 + CAUCAUCUGUAAGAAUGGCUUC 22 8047 BCL11A-6443 + UCAUCAUCUGUAAGAAUGGCUUC 23 8048 BCL11A-6444 + UUCAUCAUCUGUAAGAAUGGCUUC 24 8049 BCL11A-6445 + UCAUCUCGAUUGGUGAAG 18 8050 BCL11A-6446 + UUCAUCUCGAUUGGUGAAG 19 8051 BCL11A-5355 + UUUCAUCUCGAUUGGUGAAG 20 8052 BCL11A-6447 + UUUUCAUCUCGAUUGGUGAAG 21 8053 BCL11A-6448 + UUUUUCAUCUCGAUUGGUGAAG 22 8054 BCL11A-6449 + UUUUUUCAUCUCGAUUGGUGAAG 23 8055 BCL11A-6450 + CUUUUUUCAUCUCGAUUGGUGAAG 24 8056 BCL11A-6451 + UCCACAGCUUUUUCUAAG 18 8057 BCL11A-6452 + AUCCACAGCUUUUUCUAAG 19 8058 BCL11A-6453 + UAUCCACAGCUUUUUCUAAG 20 8059 BCL11A-6454 + UUAUCCACAGCUUUUUCUAAG 21 8060 BCL11A-6455 + CUUAUCCACAGCUUUUUCUAAG 22 8061 BCL11A-6456 + GCUUAUCCACAGCUUUUUCUAAG 23 8062 BCL11A-6457 + GGCUUAUCCACAGCUUUUUCUAAG 24 8063 BCL11A-6458 + AUCUGGCACUGCCCACAG 18 8064 BCL11A-6459 + CAUCUGGCACUGCCCACAG 19 8065 BCL11A-6460 + UCAUCUGGCACUGCCCACAG 20 8066 BCL11A-6461 + UUCAUCUGGCACUGCCCACAG 21 8067 BCL11A-6462 + GUUCAUCUGGCACUGCCCACAG 22 8068 BCL11A-6463 + AGUUCAUCUGGCACUGCCCACAG 23 8069 BCL11A-6464 + AAGUUCAUCUGGCACUGCCCACAG 24 8070 BCL11A-6465 + CUCCAUGUGCAGAACGAG 18 8071 BCL11A-6466 + GCUCCAUGUGCAGAACGAG 19 8072 BCL11A-5476 + AGCUCCAUGUGCAGAACGAG 20 8073 BCL11A-6467 + GAGCUCCAUGUGCAGAACGAG 21 8074 BCL11A-6468 + AGAGCUCCAUGUGCAGAACGAG 22 8075 BCL11A-6469 + UAGAGCUCCAUGUGCAGAACGAG 23 8076 BCL11A-6470 + UUAGAGCUCCAUGUGCAGAACGAG 24 8077 BCL11A-6471 + UGUGCAGAACGAGGGGAG 18 8078 BCL11A-6472 + AUGUGCAGAACGAGGGGAG 19 8079 BCL11A-6473 + CAUGUGCAGAACGAGGGGAG 20 8080 BCL11A-6474 + CCAUGUGCAGAACGAGGGGAG 21 8081 BCL11A-6475 + UCCAUGUGCAGAACGAGGGGAG 22 8082 BCL11A-6476 + CUCCAUGUGCAGAACGAGGGGAG 23 8083 BCL11A-6477 + GCUCCAUGUGCAGAACGAGGGGAG 24 8084 BCL11A-6478 + AGCUCCAUGUGCAGAACG 18 8085 BCL11A-6479 + GAGCUCCAUGUGCAGAACG 19 8086 BCL11A-5357 + AGAGCUCCAUGUGCAGAACG 20 8087 BCL11A-6480 + UAGAGCUCCAUGUGCAGAACG 21 8088 BCL11A-6481 + UUAGAGCUCCAUGUGCAGAACG 22 8089 BCL11A-6482 + AUUAGAGCUCCAUGUGCAGAACG 23 8090 BCL11A-6483 + GAUUAGAGCUCCAUGUGCAGAACG 24 8091 BCL11A-6484 + CUGCACUCAUCCCAGGCG 18 8092 BCL11A-6485 + UCUGCACUCAUCCCAGGCG 19 8093 BCL11A-5480 + UUCUGCACUCAUCCCAGGCG 20 8094 BCL11A-6486 + AUUCUGCACUCAUCCCAGGCG 21 8095 BCL11A-6487 + UAUUCUGCACUCAUCCCAGGCG 22 8096 BCL11A-6488 + AUAUUCUGCACUCAUCCCAGGCG 23 8097 BCL11A-6489 + CAUAUUCUGCACUCAUCCCAGGCG 24 8098 BCL11A-6490 + GGGUUUGCCUUGCUUGCG 18 8099 BCL11A-6491 + GGGGUUUGCCUUGCUUGCG 19 8100 BCL11A-6492 + UGGGGUUUGCCUUGCUUGCG 20 8101 BCL11A-6493 + CUGGGGUUUGCCUUGCUUGCG 21 8102 BCL11A-6494 + GCUGGGGUUUGCCUUGCUUGCG 22 8103 BCL11A-6495 + UGCUGGGGUUUGCCUUGCUUGCG 23 8104 BCL11A-6496 + GUGCUGGGGUUUGCCUUGCUUGCG 24 8105 BCL11A-6497 + CCAUGUGCAGAACGAGGG 18 8106 BCL11A-6498 + UCCAUGUGCAGAACGAGGG 19 8107 BCL11A-6499 + CUCCAUGUGCAGAACGAGGG 20 8108 BCL11A-6500 + GCUCCAUGUGCAGAACGAGGG 21 8109 BCL11A-6501 + AGCUCCAUGUGCAGAACGAGGG 22 8110 BCL11A-6502 + GAGCUCCAUGUGCAGAACGAGGG 23 8111 BCL11A-6503 + AGAGCUCCAUGUGCAGAACGAGGG 24 8112 BCL11A-6504 + GACAUGGUGGGCUGCGGG 18 8113 BCL11A-6505 + AGACAUGGUGGGCUGCGGG 19 8114 BCL11A-6506 + GAGACAUGGUGGGCUGCGGG 20 8115 BCL11A-6507 + CGAGACAUGGUGGGCUGCGGG 21 8116 BCL11A-6508 + GCGAGACAUGGUGGGCUGCGGG 22 8117 BCL11A-6509 + GGCGAGACAUGGUGGGCUGCGGG 23 8118 BCL11A-6510 + CGGCGAGACAUGGUGGGCUGCGGG 24 8119 BCL11A-6511 + CAUGUGCAGAACGAGGGG 18 8120 BCL11A-6512 + CCAUGUGCAGAACGAGGGG 19 8121 BCL11A-5488 + UCCAUGUGCAGAACGAGGGG 20 8122 BCL11A-6513 + CUCCAUGUGCAGAACGAGGGG 21 8123 BCL11A-6514 + GCUCCAUGUGCAGAACGAGGGG 22 8124 BCL11A-6515 + AGCUCCAUGUGCAGAACGAGGGG 23 8125 BCL11A-6516 + GAGCUCCAUGUGCAGAACGAGGGG 24 8126 BCL11A-6517 + CAAGAGGCUCGGCUGUGG 18 8127 BCL11A-6518 + UCAAGAGGCUCGGCUGUGG 19 8128 BCL11A-6519 + UUCAAGAGGCUCGGCUGUGG 20 8129 BCL11A-6520 + CUUCAAGAGGCUCGGCUGUGG 21 8130 BCL11A-6521 + GCUUCAAGAGGCUCGGCUGUGG 22 8131 BCL11A-6522 + GGCUUCAAGAGGCUCGGCUGUGG 23 8132 BCL11A-6523 + UGGCUUCAAGAGGCUCGGCUGUGG 24 8133 BCL11A-6524 + UGCUUGCGGCGAGACAUG 18 8134 BCL11A-6525 + UUGCUUGCGGCGAGACAUG 19 8135 BCL11A-6526 + CUUGCUUGCGGCGAGACAUG 20 8136 BCL11A-6527 + CCUUGCUUGCGGCGAGACAUG 21 8137 BCL11A-6528 + GCCUUGCUUGCGGCGAGACAUG 22 8138 BCL11A-6529 + UGCCUUGCUUGCGGCGAGACAUG 23 8139 BCL11A-6530 + UUGCCUUGCUUGCGGCGAGACAUG 24 8140 BCL11A-6531 + CAACUUACAAAUACCCUG 18 8141 BCL11A-6532 + UCAACUUACAAAUACCCUG 19 8142 BCL11A-5494 + CUCAACUUACAAAUACCCUG 20 8143 BCL11A-6533 + GCUCAACUUACAAAUACCCUG 21 8144 BCL11A-6534 + GGCUCAACUUACAAAUACCCUG 22 8145 BCL11A-6535 + AGGCUCAACUUACAAAUACCCUG 23 8146 BCL11A-6536 + AAGGCUCAACUUACAAAUACCCUG 24 8147 BCL11A-6537 + GUUGUACAUGUGUAGCUG 18 8148 BCL11A-6538 + AGUUGUACAUGUGUAGCUG 19 8149 BCL11A-6539 + AAGUUGUACAUGUGUAGCUG 20 8150 BCL11A-6540 + CAAGUUGUACAUGUGUAGCUG 21 8151 BCL11A-6541 + GCAAGUUGUACAUGUGUAGCUG 22 8152 BCL11A-6542 + UGCAAGUUGUACAUGUGUAGCUG 23 8153 BCL11A-6543 + UUGCAAGUUGUACAUGUGUAGCUG 24 8154 BCL11A-6544 + GCGAGACAUGGUGGGCUG 18 8155 BCL11A-6545 + GGCGAGACAUGGUGGGCUG 19 8156 BCL11A-5361 + CGGCGAGACAUGGUGGGCUG 20 8157 BCL11A-6546 + GCGGCGAGACAUGGUGGGCUG 21 8158 BCL11A-6547 + UGCGGCGAGACAUGGUGGGCUG 22 8159 BCL11A-6548 + UUGCGGCGAGACAUGGUGGGCUG 23 8160 BCL11A-6549 + CUUGCGGCGAGACAUGGUGGGCUG 24 8161 BCL11A-6550 + UUCCCGUUUGCUUAAGUG 18 8162 BCL11A-6551 + AUUCCCGUUUGCUUAAGUG 19 8163 BCL11A-6552 + AAUUCCCGUUUGCUUAAGUG 20 8164 BCL11A-6553 + GAAUUCCCGUUUGCUUAAGUG 21 8165 BCL11A-6554 + AGAAUUCCCGUUUGCUUAAGUG 22 8166 BCL11A-6555 + GAGAAUUCCCGUUUGCUUAAGUG 23 8167 BCL11A-6556 + CGAGAAUUCCCGUUUGCUUAAGUG 24 8168 BCL11A-6557 + GGAGAGGCCCCUCCAGUG 18 8169 BCL11A-6558 + AGGAGAGGCCCCUCCAGUG 19 8170 BCL11A-6559 + GAGGAGAGGCCCCUCCAGUG 20 8171 BCL11A-6560 + GGAGGAGAGGCCCCUCCAGUG 21 8172 BCL11A-6561 + GGGAGGAGAGGCCCCUCCAGUG 22 8173 BCL11A-6562 + GGGGAGGAGAGGCCCCUCCAGUG 23 8174 BCL11A-6563 + AGGGGAGGAGAGGCCCCUCCAGUG 24 8175 BCL11A-6564 + UGGCACUGCCCACAGGUG 18 8176 BCL11A-6565 + CUGGCACUGCCCACAGGUG 19 8177 BCL11A-5498 + UCUGGCACUGCCCACAGGUG 20 8178 BCL11A-6566 + AUCUGGCACUGCCCACAGGUG 21 8179 BCL11A-6567 + CAUCUGGCACUGCCCACAGGUG 22 8180 BCL11A-6568 + UCAUCUGGCACUGCCCACAGGUG 23 8181 BCL11A-6569 + UUCAUCUGGCACUGCCCACAGGUG 24 8182 BCL11A-6570 + UUUUCAUCUCGAUUGGUG 18 8183 BCL11A-6571 + UUUUUCAUCUCGAUUGGUG 19 8184 BCL11A-6572 + UUUUUUCAUCUCGAUUGGUG 20 8185 BCL11A-6573 + CUUUUUUCAUCUCGAUUGGUG 21 8186 BCL11A-6574 + GCUUUUUUCAUCUCGAUUGGUG 22 8187 BCL11A-6575 + UGCUUUUUUCAUCUCGAUUGGUG 23 8188 BCL11A-6576 + AUGCUUUUUUCAUCUCGAUUGGUG 24 8189 BCL11A-6577 + GGAUUAGAGCUCCAUGUG 18 8190 BCL11A-6578 + GGGAUUAGAGCUCCAUGUG 19 8191 BCL11A-6579 + GGGGAUUAGAGCUCCAUGUG 20 8192 BCL11A-6580 + UGGGGAUUAGAGCUCCAUGUG 21 8193 BCL11A-6581 + GUGGGGAUUAGAGCUCCAUGUG 22 8194 BCL11A-6582 + CGUGGGGAUUAGAGCUCCAUGUG 23 8195 BCL11A-6583 + GCGUGGGGAUUAGAGCUCCAUGUG 24 8196 BCL11A-6584 + CUUUUUUCAUCUCGAUUG 18 8197 BCL11A-6585 + GCUUUUUUCAUCUCGAUUG 19 8198 BCL11A-6586 + UGCUUUUUUCAUCUCGAUUG 20 8199 BCL11A-6587 + AUGCUUUUUUCAUCUCGAUUG 21 8200 BCL11A-6588 + GAUGCUUUUUUCAUCUCGAUUG 22 8201 BCL11A-6589 + GGAUGCUUUUUUCAUCUCGAUUG 23 8202 BCL11A-6590 + UGGAUGCUUUUUUCAUCUCGAUUG 24 8203 BCL11A-6591 + GAGGCUCGGCUGUGGUUG 18 8204 BCL11A-6592 + AGAGGCUCGGCUGUGGUUG 19 8205 BCL11A-6593 + AAGAGGCUCGGCUGUGGUUG 20 8206 BCL11A-6594 + CAAGAGGCUCGGCUGUGGUUG 21 8207 BCL11A-6595 + UCAAGAGGCUCGGCUGUGGUUG 22 8208 BCL11A-6596 + UUCAAGAGGCUCGGCUGUGGUUG 23 8209 BCL11A-6597 + CUUCAAGAGGCUCGGCUGUGGUUG 24 8210 BCL11A-6598 + AUAAGAAUGUCCCCCAAU 18 8211 BCL11A-6599 + AAUAAGAAUGUCCCCCAAU 19 8212 BCL11A-5502 + AAAUAAGAAUGUCCCCCAAU 20 8213 BCL11A-6600 + AAAAUAAGAAUGUCCCCCAAU 21 8214 BCL11A-6601 + AAAAAUAAGAAUGUCCCCCAAU 22 8215 BCL11A-6602 + UAAAAAUAAGAAUGUCCCCCAAU 23 8216 BCL11A-6603 + AUAAAAAUAAGAAUGUCCCCCAAU 24 8217 BCL11A-6604 + CAUCCCAGGCGUGGGGAU 18 8218 BCL11A-6605 + UCAUCCCAGGCGUGGGGAU 19 8219 BCL11A-6606 + CUCAUCCCAGGCGUGGGGAU 20 8220 BCL11A-6607 + ACUCAUCCCAGGCGUGGGGAU 21 8221 BCL11A-6608 + CACUCAUCCCAGGCGUGGGGAU 22 8222 BCL11A-6609 + GCACUCAUCCCAGGCGUGGGGAU 23 8223 BCL11A-6610 + UGCACUCAUCCCAGGCGUGGGGAU 24 8224 BCL11A-6611 + UCAACUUACAAAUACCCU 18 8225 BCL11A-6612 + CUCAACUUACAAAUACCCU 19 8226 BCL11A-6613 + GCUCAACUUACAAAUACCCU 20 8227 BCL11A-6614 + GGCUCAACUUACAAAUACCCU 21 8228 BCL11A-6615 + AGGCUCAACUUACAAAUACCCU 22 8229 BCL11A-6616 + AAGGCUCAACUUACAAAUACCCU 23 8230 BCL11A-6617 + UAAGGCUCAACUUACAAAUACCCU 24 8231 BCL11A-6618 + GGCGAGACAUGGUGGGCU 18 8232 BCL11A-6619 + CGGCGAGACAUGGUGGGCU 19 8233 BCL11A-6620 + GCGGCGAGACAUGGUGGGCU 20 8234 BCL11A-6621 + UGCGGCGAGACAUGGUGGGCU 21 8235 BCL11A-6622 + UUGCGGCGAGACAUGGUGGGCU 22 8236 BCL11A-6623 + CUUGCGGCGAGACAUGGUGGGCU 23 8237 BCL11A-6624 + GCUUGCGGCGAGACAUGGUGGGCU 24 8238 BCL11A-6625 + CAGUGCAGAAGUUUAUCU 18 8239 BCL11A-6626 + CCAGUGCAGAAGUUUAUCU 19 8240 BCL11A-6627 + UCCAGUGCAGAAGUUUAUCU 20 8241 BCL11A-6628 + CUCCAGUGCAGAAGUUUAUCU 21 8242 BCL11A-6629 + CCUCCAGUGCAGAAGUUUAUCU 22 8243 BCL11A-6630 + CCCUCCAGUGCAGAAGUUUAUCU 23 8244 BCL11A-6631 + CCCCUCCAGUGCAGAAGUUUAUCU 24 8245 BCL11A-6632 + CUGGCACUGCCCACAGGU 18 8246 BCL11A-6633 + UCUGGCACUGCCCACAGGU 19 8247 BCL11A-6634 + AUCUGGCACUGCCCACAGGU 20 8248 BCL11A-6635 + CAUCUGGCACUGCCCACAGGU 21 8249 BCL11A-6636 + UCAUCUGGCACUGCCCACAGGU 22 8250 BCL11A-6637 + UUCAUCUGGCACUGCCCACAGGU 23 8251 BCL11A-6638 + GUUCAUCUGGCACUGCCCACAGGU 24 8252 BCL11A-6639 + AAGAGGCUCGGCUGUGGU 18 8253 BCL11A-6640 + CAAGAGGCUCGGCUGUGGU 19 8254 BCL11A-5366 + UCAAGAGGCUCGGCUGUGGU 20 8255 BCL11A-6641 + UUCAAGAGGCUCGGCUGUGGU 21 8256 BCL11A-6642 + CUUCAAGAGGCUCGGCUGUGGU 22 8257 BCL11A-6643 + GCUUCAAGAGGCUCGGCUGUGGU 23 8258 BCL11A-6644 + GGCUUCAAGAGGCUCGGCUGUGGU 24 8259 BCL11A-6645 + CCUGCUAUGUGUUCCUGU 18 8260 BCL11A-6646 + ACCUGCUAUGUGUUCCUGU 19 8261 BCL11A-6647 + UACCUGCUAUGUGUUCCUGU 20 8262 BCL11A-6648 + UUACCUGCUAUGUGUUCCUGU 21 8263 BCL11A-6649 + UUUACCUGCUAUGUGUUCCUGU 22 8264 BCL11A-6650 + AUUUACCUGCUAUGUGUUCCUGU 23 8265 BCL11A-6651 + CAUUUACCUGCUAUGUGUUCCUGU 24 8266 BCL11A-6652 + GGAGGUCAUGAUCCCCUU 18 8267 BCL11A-6653 + AGGAGGUCAUGAUCCCCUU 19 8268 BCL11A-6654 + GAGGAGGUCAUGAUCCCCUU 20 8269 BCL11A-6655 + UGAGGAGGUCAUGAUCCCCUU 21 8270 BCL11A-6656 + GUGAGGAGGUCAUGAUCCCCUU 22 8271 BCL11A-6657 + GGUGAGGAGGUCAUGAUCCCCUU 23 8272 BCL11A-6658 + AGGUGAGGAGGUCAUGAUCCCCUU 24 8273 BCL11A-6659 + CUGCUAUGUGUUCCUGUU 18 8274 BCL11A-6660 + CCUGCUAUGUGUUCCUGUU 19 8275 BCL11A-5513 + ACCUGCUAUGUGUUCCUGUU 20 8276 BCL11A-6661 + UACCUGCUAUGUGUUCCUGUU 21 8277 BCL11A-6662 + UUACCUGCUAUGUGUUCCUGUU 22 8278 BCL11A-6663 + UUUACCUGCUAUGUGUUCCUGUU 23 8279 BCL11A-6664 + AUUUACCUGCUAUGUGUUCCUGUU 24 8280 BCL11A-6665 - AUUUUUAUCGAGCACAAA 18 8281 BCL11A-6666 - UAUUUUUAUCGAGCACAAA 19 8282 BCL11A-5342 - UUAUUUUUAUCGAGCACAAA 20 8283 BCL11A-6667 - CUUAUUUUUAUCGAGCACAAA 21 8284 BCL11A-6668 - UCUUAUUUUUAUCGAGCACAAA 22 8285 BCL11A-6669 - UUCUUAUUUUUAUCGAGCACAAA 23 8286 BCL11A-6670 - AUUCUUAUUUUUAUCGAGCACAAA 24 8287 BCL11A-6671 - AGAGGAAUUUGCCCCAAA 18 8288 BCL11A-6672 - UAGAGGAAUUUGCCCCAAA 19 8289 BCL11A-6673 - CUAGAGGAAUUUGCCCCAAA 20 8290 BCL11A-6674 - UCUAGAGGAAUUUGCCCCAAA 21 8291 BCL11A-6675 - AUCUAGAGGAAUUUGCCCCAAA 22 8292 BCL11A-6676 - CAUCUAGAGGAAUUUGCCCCAAA 23 8293 BCL11A-6677 - UCAUCUAGAGGAAUUUGCCCCAAA 24 8294 BCL11A-6678 - CCCCAGCACUUAAGCAAA 18 8295 BCL11A-6679 - ACCCCAGCACUUAAGCAAA 19 8296 BCL11A-5443 - AACCCCAGCACUUAAGCAAA 20 8297 BCL11A-6680 - AAACCCCAGCACUUAAGCAAA 21 8298 BCL11A-6681 - CAAACCCCAGCACUUAAGCAAA 22 8299 BCL11A-6682 - GCAAACCCCAGCACUUAAGCAAA 23 8300 BCL11A-6683 - GGCAAACCCCAGCACUUAAGCAAA 24 8301 BCL11A-6684 - UAUUUUUAUCGAGCACAA 18 8302 BCL11A-6685 - UUAUUUUUAUCGAGCACAA 19 8303 BCL11A-6686 - CUUAUUUUUAUCGAGCACAA 20 8304 BCL11A-6687 - UCUUAUUUUUAUCGAGCACAA 21 8305 BCL11A-6688 - UUCUUAUUUUUAUCGAGCACAA 22 8306 BCL11A-6689 - AUUCUUAUUUUUAUCGAGCACAA 23 8307 BCL11A-6690 - CAUUCUUAUUUUUAUCGAGCACAA 24 8308 BCL11A-6691 - CACCUUCCCCUUCACCAA 18 8309 BCL11A-6692 - CCACCUUCCCCUUCACCAA 19 8310 BCL11A-6693 - GCCACCUUCCCCUUCACCAA 20 8311 BCL11A-6694 - AGCCACCUUCCCCUUCACCAA 21 8312 BCL11A-6695 - AAGCCACCUUCCCCUUCACCAA 22 8313 BCL11A-6696 - UAAGCCACCUUCCCCUUCACCAA 23 8314 BCL11A-6697 - AUAAGCCACCUUCCCCUUCACCAA 24 8315 BCL11A-6698 - ACCCCAGCACUUAAGCAA 18 8316 BCL11A-6699 - AACCCCAGCACUUAAGCAA 19 8317 BCL11A-6700 - AAACCCCAGCACUUAAGCAA 20 8318 BCL11A-6701 - CAAACCCCAGCACUUAAGCAA 21 8319 BCL11A-6702 - GCAAACCCCAGCACUUAAGCAA 22 8320 BCL11A-6703 - GGCAAACCCCAGCACUUAAGCAA 23 8321 BCL11A-6704 - AGGCAAACCCCAGCACUUAAGCAA 24 8322 BCL11A-6705 - GGAACACAUAGCAGGUAA 18 8323 BCL11A-6706 - AGGAACACAUAGCAGGUAA 19 8324 BCL11A-6707 - CAGGAACACAUAGCAGGUAA 20 8325 BCL11A-6708 - ACAGGAACACAUAGCAGGUAA 21 8326 BCL11A-6709 - AACAGGAACACAUAGCAGGUAA 22 8327 BCL11A-6710 - AAACAGGAACACAUAGCAGGUAA 23 8328 BCL11A-6711 - CAAACAGGAACACAUAGCAGGUAA 24 8329 BCL11A-6712 - CUCCCCUCGUUCUGCACA 18 8330 BCL11A-6713 - CCUCCCCUCGUUCUGCACA 19 8331 BCL11A-5448 - UCCUCCCCUCGUUCUGCACA 20 8332 BCL11A-6714 - CUCCUCCCCUCGUUCUGCACA 21 8333 BCL11A-6715 - UCUCCUCCCCUCGUUCUGCACA 22 8334 BCL11A-6716 - CUCUCCUCCCCUCGUUCUGCACA 23 8335 BCL11A-6717 - CCUCUCCUCCCCUCGUUCUGCACA 24 8336 BCL11A-6718 - UGCCAGAUGAACUUCCCA 18 8337 BCL11A-6719 - GUGCCAGAUGAACUUCCCA 19 8338 BCL11A-6720 - AGUGCCAGAUGAACUUCCCA 20 8339 BCL11A-6721 - CAGUGCCAGAUGAACUUCCCA 21 8340 BCL11A-6722 - GCAGUGCCAGAUGAACUUCCCA 22 8341 BCL11A-6723 - GGCAGUGCCAGAUGAACUUCCCA 23 8342 BCL11A-6724 - GGGCAGUGCCAGAUGAACUUCCCA 24 8343 BCL11A-6725 - GCAGGUAAAUGAGAAGCA 18 8344 BCL11A-6726 - AGCAGGUAAAUGAGAAGCA 19 8345 BCL11A-5451 - UAGCAGGUAAAUGAGAAGCA 20 8346 BCL11A-6727 - AUAGCAGGUAAAUGAGAAGCA 21 8347 BCL11A-6728 - CAUAGCAGGUAAAUGAGAAGCA 22 8348 BCL11A-6729 - ACAUAGCAGGUAAAUGAGAAGCA 23 8349 BCL11A-6730 - CACAUAGCAGGUAAAUGAGAAGCA 24 8350 BCL11A-6731 - CACAGAUAAACUUCUGCA 18 8351 BCL11A-6732 - UCACAGAUAAACUUCUGCA 19 8352 BCL11A-6733 - UUCACAGAUAAACUUCUGCA 20 8353 BCL11A-6734 - UUUCACAGAUAAACUUCUGCA 21 8354 BCL11A-6735 - CUUUCACAGAUAAACUUCUGCA 22 8355 BCL11A-6736 - UCUUUCACAGAUAAACUUCUGCA 23 8356 BCL11A-6737 - UUCUUUCACAGAUAAACUUCUGCA 24 8357 BCL11A-6738 - CCCGUUGGGAGCUCCAGA 18 8358 BCL11A-6739 - GCCCGUUGGGAGCUCCAGA 19 8359 BCL11A-5453 - GGCCCGUUGGGAGCUCCAGA 20 8360 BCL11A-6740 - CGGCCCGUUGGGAGCUCCAGA 21 8361 BCL11A-6741 - ACGGCCCGUUGGGAGCUCCAGA 22 8362 BCL11A-6742 - CACGGCCCGUUGGGAGCUCCAGA 23 8363 BCL11A-6743 - CCACGGCCCGUUGGGAGCUCCAGA 24 8364 BCL11A-6744 - GUUUAUCAACGUCAUCUA 18 8365 BCL11A-6745 - UGUUUAUCAACGUCAUCUA 19 8366 BCL11A-6746 - UUGUUUAUCAACGUCAUCUA 20 8367 BCL11A-6747 - AUUGUUUAUCAACGUCAUCUA 21 8368 BCL11A-6748 - GAUUGUUUAUCAACGUCAUCUA 22 8369 BCL11A-6749 - CGAUUGUUUAUCAACGUCAUCUA 23 8370 BCL11A-6750 - ACGAUUGUUUAUCAACGUCAUCUA 24 8371 BCL11A-6751 - GGGACAUUCUUAUUUUUA 18 8372 BCL11A-6752 - GGGGACAUUCUUAUUUUUA 19 8373 BCL11A-6753 - GGGGGACAUUCUUAUUUUUA 20 8374 BCL11A-6754 - UGGGGGACAUUCUUAUUUUUA 21 8375 BCL11A-6755 - UUGGGGGACAUUCUUAUUUUUA 22 8376 BCL11A-6756 - AUUGGGGGACAUUCUUAUUUUUA 23 8377 BCL11A-6757 - CAUUGGGGGACAUUCUUAUUUUUA 24 8378 BCL11A-6758 - GAGGAAUUUGCCCCAAAC 18 8379 BCL11A-6759 - AGAGGAAUUUGCCCCAAAC 19 8380 BCL11A-5457 - UAGAGGAAUUUGCCCCAAAC 20 8381 BCL11A-6760 - CUAGAGGAAUUUGCCCCAAAC 21 8382 BCL11A-6761 - UCUAGAGGAAUUUGCCCCAAAC 22 8383 BCL11A-6762 - AUCUAGAGGAAUUUGCCCCAAAC 23 8384 BCL11A-6763 - CAUCUAGAGGAAUUUGCCCCAAAC 24 8385 BCL11A-6764 - ACAGAUAAACUUCUGCAC 18 8386 BCL11A-6765 - CACAGAUAAACUUCUGCAC 19 8387 BCL11A-5348 - UCACAGAUAAACUUCUGCAC 20 8388 BCL11A-6766 - UUCACAGAUAAACUUCUGCAC 21 8389 BCL11A-6767 - UUUCACAGAUAAACUUCUGCAC 22 8390 BCL11A-6768 - CUUUCACAGAUAAACUUCUGCAC 23 8391 BCL11A-6769 - UCUUUCACAGAUAAACUUCUGCAC 24 8392 BCL11A-6770 - CCUCCCCUCGUUCUGCAC 18 8393 BCL11A-6771 - UCCUCCCCUCGUUCUGCAC 19 8394 BCL11A-6772 - CUCCUCCCCUCGUUCUGCAC 20 8395 BCL11A-6773 - UCUCCUCCCCUCGUUCUGCAC 21 8396 BCL11A-6774 - CUCUCCUCCCCUCGUUCUGCAC 22 8397 BCL11A-6775 - CCUCUCCUCCCCUCGUUCUGCAC 23 8398 BCL11A-6776 - GCCUCUCCUCCCCUCGUUCUGCAC 24 8399 BCL11A-6777 - AAAAAAGCAUCCAAUCCC 18 8400 BCL11A-6778 - GAAAAAAGCAUCCAAUCCC 19 8401 BCL11A-6779 - UGAAAAAAGCAUCCAAUCCC 20 8402 BCL11A-6780 - AUGAAAAAAGCAUCCAAUCCC 21 8403 BCL11A-6781 - GAUGAAAAAAGCAUCCAAUCCC 22 8404 BCL11A-6782 - AGAUGAAAAAAGCAUCCAAUCCC 23 8405 BCL11A-6783 - GAGAUGAAAAAAGCAUCCAAUCCC 24 8406 BCL11A-6784 - AGCAGGUAAAUGAGAAGC 18 8407 BCL11A-6785 - UAGCAGGUAAAUGAGAAGC 19 8408 BCL11A-6786 - AUAGCAGGUAAAUGAGAAGC 20 8409 BCL11A-6787 - CAUAGCAGGUAAAUGAGAAGC 21 8410 BCL11A-6788 - ACAUAGCAGGUAAAUGAGAAGC 22 8411 BCL11A-6789 - CACAUAGCAGGUAAAUGAGAAGC 23 8412 BCL11A-6790 - ACACAUAGCAGGUAAAUGAGAAGC 24 8413 BCL11A-6791 - GAGCUCUAAUCCCCACGC 18 8414 BCL11A-6792 - GGAGCUCUAAUCCCCACGC 19 8415 BCL11A-6793 - UGGAGCUCUAAUCCCCACGC 20 8416 BCL11A-6794 - AUGGAGCUCUAAUCCCCACGC 21 8417 BCL11A-6795 - CAUGGAGCUCUAAUCCCCACGC 22 8418 BCL11A-6796 - ACAUGGAGCUCUAAUCCCCACGC 23 8419 BCL11A-6797 - CACAUGGAGCUCUAAUCCCCACGC 24 8420 BCL11A-6798 - UUGGCAUCCAGGUCACGC 18 8421 BCL11A-6799 - GUUGGCAUCCAGGUCACGC 19 8422 BCL11A-6800 - GGUUGGCAUCCAGGUCACGC 20 8423 BCL11A-6801 - AGGUUGGCAUCCAGGUCACGC 21 8424 BCL11A-6802 - GAGGUUGGCAUCCAGGUCACGC 22 8425 BCL11A-6803 - GGAGGUUGGCAUCCAGGUCACGC 23 8426 BCL11A-6804 - UGGAGGUUGGCAUCCAGGUCACGC 24 8427 BCL11A-6805 - UUGUUUAUCAACGUCAUC 18 8428 BCL11A-6806 - AUUGUUUAUCAACGUCAUC 19 8429 BCL11A-6807 - GAUUGUUUAUCAACGUCAUC 20 8430 BCL11A-6808 - CGAUUGUUUAUCAACGUCAUC 21 8431 BCL11A-6809 - ACGAUUGUUUAUCAACGUCAUC 22 8432 BCL11A-6810 - GACGAUUGUUUAUCAACGUCAUC 23 8433 BCL11A-6811 - UGACGAUUGUUUAUCAACGUCAUC 24 8434 BCL11A-6812 - CAACCACAGCCGAGCCUC 18 8435 BCL11A-6813 - CCAACCACAGCCGAGCCUC 19 8436 BCL11A-6814 - UCCAACCACAGCCGAGCCUC 20 8437 BCL11A-6815 - CUCCAACCACAGCCGAGCCUC 21 8438 BCL11A-6816 - UCUCCAACCACAGCCGAGCCUC 22 8439 BCL11A-6817 - UUCUCCAACCACAGCCGAGCCUC 23 8440 BCL11A-6818 - UUUCUCCAACCACAGCCGAGCCUC 24 8441 BCL11A-6819 - ACGGCCCGUUGGGAGCUC 18 8442 BCL11A-6820 - CACGGCCCGUUGGGAGCUC 19 8443 BCL11A-6821 - CCACGGCCCGUUGGGAGCUC 20 8444 BCL11A-6822 - ACCACGGCCCGUUGGGAGCUC 21 8445 BCL11A-6823 - GACCACGGCCCGUUGGGAGCUC 22 8446 BCL11A-6824 - AGACCACGGCCCGUUGGGAGCUC 23 8447 BCL11A-6825 - CAGACCACGGCCCGUUGGGAGCUC 24 8448 BCL11A-6826 - AUUAUUUUGCAGGUAAAG 18 8449 BCL11A-6827 - UAUUAUUUUGCAGGUAAAG 19 8450 BCL11A-6828 - GUAUUAUUUUGCAGGUAAAG 20 8451 BCL11A-6829 - UGUAUUAUUUUGCAGGUAAAG 21 8452 BCL11A-6830 - UUGUAUUAUUUUGCAGGUAAAG 22 8453 BCL11A-6831 - GUUGUAUUAUUUUGCAGGUAAAG 23 8454 BCL11A-6832 - UGUUGUAUUAUUUUGCAGGUAAAG 24 8455 BCL11A-6833 - AGGUAAAUGAGAAGCAAG 18 8456 BCL11A-6834 - CAGGUAAAUGAGAAGCAAG 19 8457 BCL11A-6835 - GCAGGUAAAUGAGAAGCAAG 20 8458 BCL11A-6836 - AGCAGGUAAAUGAGAAGCAAG 21 8459 BCL11A-6837 - UAGCAGGUAAAUGAGAAGCAAG 22 8460 BCL11A-6838 - AUAGCAGGUAAAUGAGAAGCAAG 23 8461 BCL11A-6839 - CAUAGCAGGUAAAUGAGAAGCAAG 24 8462 BCL11A-6840 - CCGCAGGGUAUUUGUAAG 18 8463 BCL11A-6841 - CCCGCAGGGUAUUUGUAAG 19 8464 BCL11A-6842 - CCCCGCAGGGUAUUUGUAAG 20 8465 BCL11A-6843 - GCCCCGCAGGGUAUUUGUAAG 21 8466 BCL11A-6844 - UGCCCCGCAGGGUAUUUGUAAG 22 8467 BCL11A-6845 - AUGCCCCGCAGGGUAUUUGUAAG 23 8468 BCL11A-6846 - UAUGCCCCGCAGGGUAUUUGUAAG 24 8469 BCL11A-6847 - UUGUUUCUCCAACCACAG 18 8470 BCL11A-6848 - UUUGUUUCUCCAACCACAG 19 8471 BCL11A-6849 - UUUUGUUUCUCCAACCACAG 20 8472 BCL11A-6850 - CUUUUGUUUCUCCAACCACAG 21 8473 BCL11A-6851 - GCUUUUGUUUCUCCAACCACAG 22 8474 BCL11A-6852 - UGCUUUUGUUUCUCCAACCACAG 23 8475 BCL11A-6853 - GUGCUUUUGUUUCUCCAACCACAG 24 8476 BCL11A-6854 - ACCUGUGGGCAGUGCCAG 18 8477 BCL11A-6855 - CACCUGUGGGCAGUGCCAG 19 8478 BCL11A-6856 - UCACCUGUGGGCAGUGCCAG 20 8479 BCL11A-6857 - CUCACCUGUGGGCAGUGCCAG 21 8480 BCL11A-6858 - CCUCACCUGUGGGCAGUGCCAG 22 8481 BCL11A-6859 - UCCUCACCUGUGGGCAGUGCCAG 23 8482 BCL11A-6860 - CUCCUCACCUGUGGGCAGUGCCAG 24 8483 BCL11A-6861 - GCCCGUUGGGAGCUCCAG 18 8484 BCL11A-6862 - GGCCCGUUGGGAGCUCCAG 19 8485 BCL11A-6863 - CGGCCCGUUGGGAGCUCCAG 20 8486 BCL11A-6864 - ACGGCCCGUUGGGAGCUCCAG 21 8487 BCL11A-6865 - CACGGCCCGUUGGGAGCUCCAG 22 8488 BCL11A-6866 - CCACGGCCCGUUGGGAGCUCCAG 23 8489 BCL11A-6867 - ACCACGGCCCGUUGGGAGCUCCAG 24 8490 BCL11A-6868 - UCCCCUUCACCAAUCGAG 18 8491 BCL11A-6869 - UUCCCCUUCACCAAUCGAG 19 8492 BCL11A-6870 - CUUCCCCUUCACCAAUCGAG 20 8493 BCL11A-6871 - CCUUCCCCUUCACCAAUCGAG 21 8494 BCL11A-6872 - ACCUUCCCCUUCACCAAUCGAG 22 8495 BCL11A-6873 - CACCUUCCCCUUCACCAAUCGAG 23 8496 BCL11A-6874 - CCACCUUCCCCUUCACCAAUCGAG 24 8497 BCL11A-6875 - GAACCAGACCACGGCCCG 18 8498 BCL11A-6876 - UGAACCAGACCACGGCCCG 19 8499 BCL11A-6877 - AUGAACCAGACCACGGCCCG 20 8500 BCL11A-6878 - GAUGAACCAGACCACGGCCCG 21 8501 BCL11A-6879 - UGAUGAACCAGACCACGGCCCG 22 8502 BCL11A-6880 - AUGAUGAACCAGACCACGGCCCG 23 8503 BCL11A-6881 - GAUGAUGAACCAGACCACGGCCCG 24 8504 BCL11A-6882 - AAAAAGCAUCCAAUCCCG 18 8505 BCL11A-6883 - AAAAAAGCAUCCAAUCCCG 19 8506 BCL11A-5358 - GAAAAAAGCAUCCAAUCCCG 20 8507 BCL11A-6884 - UGAAAAAAGCAUCCAAUCCCG 21 8508 BCL11A-6885 - AUGAAAAAAGCAUCCAAUCCCG 22 8509 BCL11A-6886 - GAUGAAAAAAGCAUCCAAUCCCG 23 8510 BCL11A-6887 - AGAUGAAAAAAGCAUCCAAUCCCG 24 8511 BCL11A-6888 - GAUAAACUUCUGCACUGG 18 8512 BCL11A-6889 - AGAUAAACUUCUGCACUGG 19 8513 BCL11A-5360 - CAGAUAAACUUCUGCACUGG 20 8514 BCL11A-6890 - ACAGAUAAACUUCUGCACUGG 21 8515 BCL11A-6891 - CACAGAUAAACUUCUGCACUGG 22 8516 BCL11A-6892 - UCACAGAUAAACUUCUGCACUGG 23 8517 BCL11A-6893 - UUCACAGAUAAACUUCUGCACUGG 24 8518 BCL11A-6894 - AAGCCAUUCUUACAGAUG 18 8519 BCL11A-6895 - GAAGCCAUUCUUACAGAUG 19 8520 BCL11A-6896 - UGAAGCCAUUCUUACAGAUG 20 8521 BCL11A-6897 - UUGAAGCCAUUCUUACAGAUG 21 8522 BCL11A-6898 - CUUGAAGCCAUUCUUACAGAUG 22 8523 BCL11A-6899 - UCUUGAAGCCAUUCUUACAGAUG 23 8524 BCL11A-6900 - CUCUUGAAGCCAUUCUUACAGAUG 24 8525 BCL11A-6901 - AGAUAAACUUCUGCACUG 18 8526 BCL11A-6902 - CAGAUAAACUUCUGCACUG 19 8527 BCL11A-6903 - ACAGAUAAACUUCUGCACUG 20 8528 BCL11A-6904 - CACAGAUAAACUUCUGCACUG 21 8529 BCL11A-6905 - UCACAGAUAAACUUCUGCACUG 22 8530 BCL11A-6906 - UUCACAGAUAAACUUCUGCACUG 23 8531 BCL11A-6907 - UUUCACAGAUAAACUUCUGCACUG 24 8532 BCL11A-6908 - CAGAUGAACUUCCCAUUG 18 8533 BCL11A-6909 - CCAGAUGAACUUCCCAUUG 19 8534 BCL11A-5499 - GCCAGAUGAACUUCCCAUUG 20 8535 BCL11A-6910 - UGCCAGAUGAACUUCCCAUUG 21 8536 BCL11A-6911 - GUGCCAGAUGAACUUCCCAUUG 22 8537 BCL11A-6912 - AGUGCCAGAUGAACUUCCCAUUG 23 8538 BCL11A-6913 - CAGUGCCAGAUGAACUUCCCAUUG 24 8539 BCL11A-6914 - AACACAUAGCAGGUAAAU 18 8540 BCL11A-6915 - GAACACAUAGCAGGUAAAU 19 8541 BCL11A-6916 - GGAACACAUAGCAGGUAAAU 20 8542 BCL11A-6917 - AGGAACACAUAGCAGGUAAAU 21 8543 BCL11A-6918 - CAGGAACACAUAGCAGGUAAAU 22 8544 BCL11A-6919 - ACAGGAACACAUAGCAGGUAAAU 23 8545 BCL11A-6920 - AACAGGAACACAUAGCAGGUAAAU 24 8546 BCL11A-6921 - GCCAGAUGAACUUCCCAU 18 8547 BCL11A-6922 - UGCCAGAUGAACUUCCCAU 19 8548 BCL11A-5503 - GUGCCAGAUGAACUUCCCAU 20 8549 BCL11A-6923 - AGUGCCAGAUGAACUUCCCAU 21 8550 BCL11A-6924 - CAGUGCCAGAUGAACUUCCCAU 22 8551 BCL11A-6925 - GCAGUGCCAGAUGAACUUCCCAU 23 8552 BCL11A-6926 - GGCAGUGCCAGAUGAACUUCCCAU 24 8553 BCL11A-6927 - AUCAUGACCUCCUCACCU 18 8554 BCL11A-6928 - GAUCAUGACCUCCUCACCU 19 8555 BCL11A-6929 - GGAUCAUGACCUCCUCACCU 20 8556 BCL11A-6930 - GGGAUCAUGACCUCCUCACCU 21 8557 BCL11A-6931 - GGGGAUCAUGACCUCCUCACCU 22 8558 BCL11A-6932 - AGGGGAUCAUGACCUCCUCACCU 23 8559 BCL11A-6933 - AAGGGGAUCAUGACCUCCUCACCU 24 8560 BCL11A-6934 - GCAAUGGCAGCCUCUGCU 18 8561 BCL11A-6935 - UGCAAUGGCAGCCUCUGCU 19 8562 BCL11A-6936 - AUGCAAUGGCAGCCUCUGCU 20 8563 BCL11A-6937 - AAUGCAAUGGCAGCCUCUGCU 21 8564 BCL11A-6938 - CAAUGCAAUGGCAGCCUCUGCU 22 8565 BCL11A-6939 - ACAAUGCAAUGGCAGCCUCUGCU 23 8566 BCL11A-6940 - AACAAUGCAAUGGCAGCCUCUGCU 24 8567 BCL11A-6941 - AACCAGACCACGGCCCGU 18 8568 BCL11A-6942 - GAACCAGACCACGGCCCGU 19 8569 BCL11A-5363 - UGAACCAGACCACGGCCCGU 20 8570 BCL11A-6943 - AUGAACCAGACCACGGCCCGU 21 8571 BCL11A-6944 - GAUGAACCAGACCACGGCCCGU 22 8572 BCL11A-6945 - UGAUGAACCAGACCACGGCCCGU 23 8573 BCL11A-6946 - AUGAUGAACCAGACCACGGCCCGU 24 8574 BCL11A-6947 - CCAGAUGAACUUCCCAUU 18 8575 BCL11A-6948 - GCCAGAUGAACUUCCCAUU 19 8576 BCL11A-5511 - UGCCAGAUGAACUUCCCAUU 20 8577 BCL11A-6949 - GUGCCAGAUGAACUUCCCAUU 21 8578 BCL11A-6950 - AGUGCCAGAUGAACUUCCCAUU 22 8579 BCL11A-6951 - CAGUGCCAGAUGAACUUCCCAUU 23 8580 BCL11A-6952 - GCAGUGCCAGAUGAACUUCCCAUU 24 8581 BCL11A-6953 - ACCAGACCACGGCCCGUU 18 8582 BCL11A-6954 - AACCAGACCACGGCCCGUU 19 8583 BCL11A-5512 - GAACCAGACCACGGCCCGUU 20 8584 BCL11A-6955 - UGAACCAGACCACGGCCCGUU 21 8585 BCL11A-6956 - AUGAACCAGACCACGGCCCGUU 22 8586 BCL11A-6957 - GAUGAACCAGACCACGGCCCGUU 23 8587 BCL11A-6958 - UGAUGAACCAGACCACGGCCCGUU 24 8588

Table 16D provides exemplary targeting domains for knocking out the BCL11A gene selected according to the fourth tier parameters. The targeting domains fall in the coding sequence of the gene, downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon of the gene), and the PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 16D 4th Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-6959 + GUAUUCUUAGCAGGUUAA 18 8589 BCL11A-6960 + GGUAUUCUUAGCAGGUUAA 19 8590 BCL11A-5890 + UGGUAUUCUUAGCAGGUUAA 20 8591 BCL11A-6961 + CUGGUAUUCUUAGCAGGUUAA 21 8592 BCL11A-6962 + CCUGGUAUUCUUAGCAGGUUAA 22 8593 BCL11A-6963 + UCCUGGUAUUCUUAGCAGGUUAA 23 8594 BCL11A-6964 + AUCCUGGUAUUCUUAGCAGGUUAA 24 8595 BCL11A-6965 + CGGGAGGCUCCAUAGCCA 18 8596 BCL11A-6966 + GCGGGAGGCUCCAUAGCCA 19 8597 BCL11A-6967 + GGCGGGAGGCUCCAUAGCCA 20 8598 BCL11A-6968 + UGGCGGGAGGCUCCAUAGCCA 21 8599 BCL11A-6969 + AUGGCGGGAGGCUCCAUAGCCA 22 8600 BCL11A-6970 + CAUGGCGGGAGGCUCCAUAGCCA 23 8601 BCL11A-6971 + CCAUGGCGGGAGGCUCCAUAGCCA 24 8602 BCL11A-6972 + GGUCCGACUCGCCGGCCA 18 8603 BCL11A-6973 + CGGUCCGACUCGCCGGCCA 19 8604 BCL11A-6974 + GCGGUCCGACUCGCCGGCCA 20 8605 BCL11A-6975 + UGCGGUCCGACUCGCCGGCCA 21 8606 BCL11A-6976 + AUGCGGUCCGACUCGCCGGCCA 22 8607 BCL11A-6977 + UAUGCGGUCCGACUCGCCGGCCA 23 8608 BCL11A-6978 + CUAUGCGGUCCGACUCGCCGGCCA 24 8609 BCL11A-6979 + AGUCUCCGAAGCUAAGGA 18 8610 BCL11A-6980 + GAGUCUCCGAAGCUAAGGA 19 8611 BCL11A-5923 + GGAGUCUCCGAAGCUAAGGA 20 8612 BCL11A-6981 + UGGAGUCUCCGAAGCUAAGGA 21 8613 BCL11A-6982 + CUGGAGUCUCCGAAGCUAAGGA 22 8614 BCL11A-6983 + UCUGGAGUCUCCGAAGCUAAGGA 23 8615 BCL11A-6984 + GUCUGGAGUCUCCGAAGCUAAGGA 24 8616 BCL11A-6985 + GGACUAAACAGGGGGGGA 18 8617 BCL11A-6986 + UGGACUAAACAGGGGGGGA 19 8618 BCL11A-6987 + GUGGACUAAACAGGGGGGGA 20 8619 BCL11A-6988 + GGUGGACUAAACAGGGGGGGA 21 8620 BCL11A-6989 + UGGUGGACUAAACAGGGGGGGA 22 8621 BCL11A-6990 + GUGGUGGACUAAACAGGGGGGGA 23 8622 BCL11A-6991 + GGUGGUGGACUAAACAGGGGGGGA 24 8623 BCL11A-6992 + UUCUGCACCUAGUCCUGA 18 8624 BCL11A-6993 + AUUCUGCACCUAGUCCUGA 19 8625 BCL11A-5937 + CAUUCUGCACCUAGUCCUGA 20 8626 BCL11A-6994 + ACAUUCUGCACCUAGUCCUGA 21 8627 BCL11A-6995 + GACAUUCUGCACCUAGUCCUGA 22 8628 BCL11A-6996 + GGACAUUCUGCACCUAGUCCUGA 23 8629 BCL11A-6997 + AGGACAUUCUGCACCUAGUCCUGA 24 8630 BCL11A-6998 + GCACCCUGUCAAAGGCAC 18 8631 BCL11A-6999 + AGCACCCUGUCAAAGGCAC 19 8632 BCL11A-7000 + CAGCACCCUGUCAAAGGCAC 20 8633 BCL11A-7001 + GCAGCACCCUGUCAAAGGCAC 21 8634 BCL11A-7002 + CGCAGCACCCUGUCAAAGGCAC 22 8635 BCL11A-7003 + CCGCAGCACCCUGUCAAAGGCAC 23 8636 BCL11A-7004 + ACCGCAGCACCCUGUCAAAGGCAC 24 8637 BCL11A-7005 + UAAGUAGAUUCUUAAUCC 18 8638 BCL11A-7006 + CUAAGUAGAUUCUUAAUCC 19 8639 BCL11A-7007 + UCUAAGUAGAUUCUUAAUCC 20 8640 BCL11A-7008 + UUCUAAGUAGAUUCUUAAUCC 21 8641 BCL11A-7009 + UUUCUAAGUAGAUUCUUAAUCC 22 8642 BCL11A-7010 + CUUUCUAAGUAGAUUCUUAAUCC 23 8643 BCL11A-7011 + GCUUUCUAAGUAGAUUCUUAAUCC 24 8644 BCL11A-7012 + GGCGGCUUGCUACCUGGC 18 8645 BCL11A-7013 + GGGCGGCUUGCUACCUGGC 19 8646 BCL11A-6036 + AGGGCGGCUUGCUACCUGGC 20 8647 BCL11A-7014 + AAGGGCGGCUUGCUACCUGGC 21 8648 BCL11A-7015 + GAAGGGCGGCUUGCUACCUGGC 22 8649 BCL11A-7016 + GGAAGGGCGGCUUGCUACCUGGC 23 8650 BCL11A-7017 + AGGAAGGGCGGCUUGCUACCUGGC 24 8651 BCL11A-7018 + GCGCUUCAGCUUGCUGGC 18 8652 BCL11A-7019 + GGCGCUUCAGCUUGCUGGC 19 8653 BCL11A-7020 + UGGCGCUUCAGCUUGCUGGC 20 8654 BCL11A-7021 + GUGGCGCUUCAGCUUGCUGGC 21 8655 BCL11A-7022 + UGUGGCGCUUCAGCUUGCUGGC 22 8656 BCL11A-7023 + AUGUGGCGCUUCAGCUUGCUGGC 23 8657 BCL11A-7024 + CAUGUGGCGCUUCAGCUUGCUGGC 24 8658 BCL11A-7025 + CUCCUCGUCCCCGUUCUC 18 8659 BCL11A-7026 + CCUCCUCGUCCCCGUUCUC 19 8660 BCL11A-6050 + UCCUCCUCGUCCCCGUUCUC 20 8661 BCL11A-7027 + UUCCUCCUCGUCCCCGUUCUC 21 8662 BCL11A-7028 + CUUCCUCCUCGUCCCCGUUCUC 22 8663 BCL11A-7029 + UCUUCCUCCUCGUCCCCGUUCUC 23 8664 BCL11A-7030 + CUCUUCCUCCUCGUCCCCGUUCUC 24 8665 BCL11A-7031 + AGGCAAAAGGCGAUUGUC 18 8666 BCL11A-7032 + GAGGCAAAAGGCGAUUGUC 19 8667 BCL11A-6054 + GGAGGCAAAAGGCGAUUGUC 20 8668 BCL11A-7033 + AGGAGGCAAAAGGCGAUUGUC 21 8669 BCL11A-7034 + GAGGAGGCAAAAGGCGAUUGUC 22 8670 BCL11A-7035 + CGAGGAGGCAAAAGGCGAUUGUC 23 8671 BCL11A-7036 + ACGAGGAGGCAAAAGGCGAUUGUC 24 8672 BCL11A-7037 + AGCUCUCUGGGUACUACG 18 8673 BCL11A-7038 + GAGCUCUCUGGGUACUACG 19 8674 BCL11A-7039 + UGAGCUCUCUGGGUACUACG 20 8675 BCL11A-7040 + UUGAGCUCUCUGGGUACUACG 21 8676 BCL11A-7041 + CUUGAGCUCUCUGGGUACUACG 22 8677 BCL11A-7042 + UCUUGAGCUCUCUGGGUACUACG 23 8678 BCL11A-7043 + AUCUUGAGCUCUCUGGGUACUACG 24 8679 BCL11A-7044 + UGAAGGGAUACCAACCCG 18 8680 BCL11A-7045 + CUGAAGGGAUACCAACCCG 19 8681 BCL11A-6084 + CCUGAAGGGAUACCAACCCG 20 8682 BCL11A-7046 + UCCUGAAGGGAUACCAACCCG 21 8683 BCL11A-7047 + GUCCUGAAGGGAUACCAACCCG 22 8684 BCL11A-7048 + AGUCCUGAAGGGAUACCAACCCG 23 8685 BCL11A-7049 + UAGUCCUGAAGGGAUACCAACCCG 24 8686 BCL11A-7050 + GCAAACUCCCGUUCUCCG 18 8687 BCL11A-7051 + CGCAAACUCCCGUUCUCCG 19 8688 BCL11A-6094 + GCGCAAACUCCCGUUCUCCG 20 8689 BCL11A-7052 + AGCGCAAACUCCCGUUCUCCG 21 8690 BCL11A-7053 + AAGCGCAAACUCCCGUUCUCCG 22 8691 BCL11A-7054 + GAAGCGCAAACUCCCGUUCUCCG 23 8692 BCL11A-7055 + AGAAGCGCAAACUCCCGUUCUCCG 24 8693 BCL11A-7056 + GGCUGGGAGGGAGGAGGG 18 8694 BCL11A-7057 + GGGCUGGGAGGGAGGAGGG 19 8695 BCL11A-7058 + GGGGCUGGGAGGGAGGAGGG 20 8696 BCL11A-7059 + GGGGGCUGGGAGGGAGGAGGG 21 8697 BCL11A-7060 + CGGGGGCUGGGAGGGAGGAGGG 22 8698 BCL11A-7061 + CCGGGGGCUGGGAGGGAGGAGGG 23 8699 BCL11A-7062 + ACCGGGGGCUGGGAGGGAGGAGGG 24 8700 BCL11A-7063 + UGGUGGACUAAACAGGGG 18 8701 BCL11A-7064 + GUGGUGGACUAAACAGGGG 19 8702 BCL11A-6139 + GGUGGUGGACUAAACAGGGG 20 8703 BCL11A-7065 + CGGUGGUGGACUAAACAGGGG 21 8704 BCL11A-7066 + UCGGUGGUGGACUAAACAGGGG 22 8705 BCL11A-7067 + CUCGGUGGUGGACUAAACAGGGG 23 8706 BCL11A-7068 + UCUCGGUGGUGGACUAAACAGGGG 24 8707 BCL11A-7069 + AAGAGAAACCAUGCACUG 18 8708 BCL11A-7070 + CAAGAGAAACCAUGCACUG 19 8709 BCL11A-7071 + GCAAGAGAAACCAUGCACUG 20 8710 BCL11A-7072 + UGCAAGAGAAACCAUGCACUG 21 8711 BCL11A-7073 + UUGCAAGAGAAACCAUGCACUG 22 8712 BCL11A-7074 + GUUGCAAGAGAAACCAUGCACUG 23 8713 BCL11A-7075 + UGUUGCAAGAGAAACCAUGCACUG 24 8714 BCL11A-7076 + GUCAAAGGCACUCGGGUG 18 8715 BCL11A-7077 + UGUCAAAGGCACUCGGGUG 19 8716 BCL11A-7078 + CUGUCAAAGGCACUCGGGUG 20 8717 BCL11A-7079 + CCUGUCAAAGGCACUCGGGUG 21 8718 BCL11A-7080 + CCCUGUCAAAGGCACUCGGGUG 22 8719 BCL11A-7081 + ACCCUGUCAAAGGCACUCGGGUG 23 8720 BCL11A-7082 + CACCCUGUCAAAGGCACUCGGGUG 24 8721 BCL11A-7083 + CCCACCAAGUCGCUGGUG 18 8722 BCL11A-7084 + GCCCACCAAGUCGCUGGUG 19 8723 BCL11A-7085 + UGCCCACCAAGUCGCUGGUG 20 8724 BCL11A-7086 + CUGCCCACCAAGUCGCUGGUG 21 8725 BCL11A-7087 + GCUGCCCACCAAGUCGCUGGUG 22 8726 BCL11A-7088 + CGCUGCCCACCAAGUCGCUGGUG 23 8727 BCL11A-7089 + GCGCUGCCCACCAAGUCGCUGGUG 24 8728 BCL11A-7090 + GGGGUUAUUGUCUGCAAU 18 8729 BCL11A-7091 + AGGGGUUAUUGUCUGCAAU 19 8730 BCL11A-7092 + AAGGGGUUAUUGUCUGCAAU 20 8731 BCL11A-7093 + AAAGGGGUUAUUGUCUGCAAU 21 8732 BCL11A-7094 + UAAAGGGGUUAUUGUCUGCAAU 22 8733 BCL11A-7095 + UUAAAGGGGUUAUUGUCUGCAAU 23 8734 BCL11A-7096 + GUUAAAGGGGUUAUUGUCUGCAAU 24 8735 BCL11A-7097 + CUGGGUACUACGCCGAAU 18 8736 BCL11A-7098 + UCUGGGUACUACGCCGAAU 19 8737 BCL11A-6182 + CUCUGGGUACUACGCCGAAU 20 8738 BCL11A-7099 + UCUCUGGGUACUACGCCGAAU 21 8739 BCL11A-7100 + CUCUCUGGGUACUACGCCGAAU 22 8740 BCL11A-7101 + GCUCUCUGGGUACUACGCCGAAU 23 8741 BCL11A-7102 + AGCUCUCUGGGUACUACGCCGAAU 24 8742 BCL11A-7103 + CGUAGCCGGCGAGCCACU 18 8743 BCL11A-7104 + GCGUAGCCGGCGAGCCACU 19 8744 BCL11A-7105 + CGCGUAGCCGGCGAGCCACU 20 8745 BCL11A-7106 + CCGCGUAGCCGGCGAGCCACU 21 8746 BCL11A-7107 + GCCGCGUAGCCGGCGAGCCACU 22 8747 BCL11A-7108 + GGCCGCGUAGCCGGCGAGCCACU 23 8748 BCL11A-7109 + AGGCCGCGUAGCCGGCGAGCCACU 24 8749 BCL11A-7110 + CCACACAUCUUGAGCUCU 18 8750 BCL11A-7111 + GCCACACAUCUUGAGCUCU 19 8751 BCL11A-7112 + UGCCACACAUCUUGAGCUCU 20 8752 BCL11A-7113 + CUGCCACACAUCUUGAGCUCU 21 8753 BCL11A-7114 + ACUGCCACACAUCUUGAGCUCU 22 8754 BCL11A-7115 + AACUGCCACACAUCUUGAGCUCU 23 8755 BCL11A-7116 + AAACUGCCACACAUCUUGAGCUCU 24 8756 BCL11A-7117 + CGUUCUCCGGGAUCAGGU 18 8757 BCL11A-7118 + CCGUUCUCCGGGAUCAGGU 19 8758 BCL11A-6223 + CCCGUUCUCCGGGAUCAGGU 20 8759 BCL11A-7119 + CCCCGUUCUCCGGGAUCAGGU 21 8760 BCL11A-7120 + UCCCCGUUCUCCGGGAUCAGGU 22 8761 BCL11A-7121 + GUCCCCGUUCUCCGGGAUCAGGU 23 8762 BCL11A-7122 + CGUCCCCGUUCUCCGGGAUCAGGU 24 8763 BCL11A-7123 + CCAGGCGCUCUAUGCGGU 18 8764 BCL11A-7124 + CCCAGGCGCUCUAUGCGGU 19 8765 BCL11A-6226 + CCCCAGGCGCUCUAUGCGGU 20 8766 BCL11A-7125 + CCCCCAGGCGCUCUAUGCGGU 21 8767 BCL11A-7126 + GCCCCCAGGCGCUCUAUGCGGU 22 8768 BCL11A-7127 + CGCCCCCAGGCGCUCUAUGCGGU 23 8769 BCL11A-7128 + CCGCCCCCAGGCGCUCUAUGCGGU 24 8770 BCL11A-7129 - UUCCCAGCCACCUCUCCA 18 8771 BCL11A-7130 - CUUCCCAGCCACCUCUCCA 19 8772 BCL11A-5903 - CCUUCCCAGCCACCUCUCCA 20 8773 BCL11A-7131 - UCCUUCCCAGCCACCUCUCCA 21 8774 BCL11A-7132 - GUCCUUCCCAGCCACCUCUCCA 22 8775 BCL11A-7133 - UGUCCUUCCCAGCCACCUCUCCA 23 8776 BCL11A-7134 - AUGUCCUUCCCAGCCACCUCUCCA 24 8777 BCL11A-7135 - AGCGCAUCAAGCUCGAGA 18 8778 BCL11A-7136 - AAGCGCAUCAAGCUCGAGA 19 8779 BCL11A-5919 - UAAGCGCAUCAAGCUCGAGA 20 8780 BCL11A-7137 - CUAAGCGCAUCAAGCUCGAGA 21 8781 BCL11A-7138 - UCUAAGCGCAUCAAGCUCGAGA 22 8782 BCL11A-7139 - CUCUAAGCGCAUCAAGCUCGAGA 23 8783 BCL11A-7140 - UCUCUAAGCGCAUCAAGCUCGAGA 24 8784 BCL11A-7141 - GGAGCUGACGGAGAGCGA 18 8785 BCL11A-7142 - AGGAGCUGACGGAGAGCGA 19 8786 BCL11A-7143 - GAGGAGCUGACGGAGAGCGA 20 8787 BCL11A-7144 - GGAGGAGCUGACGGAGAGCGA 21 8788 BCL11A-7145 - AGGAGGAGCUGACGGAGAGCGA 22 8789 BCL11A-7146 - GAGGAGGAGCUGACGGAGAGCGA 23 8790 BCL11A-7147 - GGAGGAGGAGCUGACGGAGAGCGA 24 8791 BCL11A-7148 - UCACCCGAGUGCCUUUGA 18 8792 BCL11A-7149 - AUCACCCGAGUGCCUUUGA 19 8793 BCL11A-7150 - CAUCACCCGAGUGCCUUUGA 20 8794 BCL11A-7151 - CCAUCACCCGAGUGCCUUUGA 21 8795 BCL11A-7152 - CCCAUCACCCGAGUGCCUUUGA 22 8796 BCL11A-7153 - ACCCAUCACCCGAGUGCCUUUGA 23 8797 BCL11A-7154 - CACCCAUCACCCGAGUGCCUUUGA 24 8798 BCL11A-7155 - GAGCACUCCUCGGAGAAC 18 8799 BCL11A-7156 - GGAGCACUCCUCGGAGAAC 19 8800 BCL11A-5949 - CGGAGCACUCCUCGGAGAAC 20 8801 BCL11A-7157 - UCGGAGCACUCCUCGGAGAAC 21 8802 BCL11A-7158 - GUCGGAGCACUCCUCGGAGAAC 22 8803 BCL11A-7159 - CGUCGGAGCACUCCUCGGAGAAC 23 8804 BCL11A-7160 - UCGUCGGAGCACUCCUCGGAGAAC 24 8805 BCL11A-7161 - GCCCUGGCCACCCAUCAC 18 8806 BCL11A-7162 - GGCCCUGGCCACCCAUCAC 19 8807 BCL11A-7163 - UGGCCCUGGCCACCCAUCAC 20 8808 BCL11A-7164 - AUGGCCCUGGCCACCCAUCAC 21 8809 BCL11A-7165 - GAUGGCCCUGGCCACCCAUCAC 22 8810 BCL11A-7166 - AGAUGGCCCUGGCCACCCAUCAC 23 8811 BCL11A-7167 - GAGAUGGCCCUGGCCACCCAUCAC 24 8812 BCL11A-7168 - UUAACCUGCUAAGAAUAC 18 8813 BCL11A-7169 - UUUAACCUGCUAAGAAUAC 19 8814 BCL11A-7170 - CUUUAACCUGCUAAGAAUAC 20 8815 BCL11A-7171 - CCUUUAACCUGCUAAGAAUAC 21 8816 BCL11A-7172 - CCCUUUAACCUGCUAAGAAUAC 22 8817 BCL11A-7173 - CCCCUUUAACCUGCUAAGAAUAC 23 8818 BCL11A-7174 - ACCCCUUUAACCUGCUAAGAAUAC 24 8819 BCL11A-7175 - CGGAAGUCCCCUGACCCC 18 8820 BCL11A-7176 - ACGGAAGUCCCCUGACCCC 19 8821 BCL11A-7177 - CACGGAAGUCCCCUGACCCC 20 8822 BCL11A-7178 - ACACGGAAGUCCCCUGACCCC 21 8823 BCL11A-7179 - AACACGGAAGUCCCCUGACCCC 22 8824 BCL11A-7180 - GAACACGGAAGUCCCCUGACCCC 23 8825 BCL11A-7181 - CGAACACGGAAGUCCCCUGACCCC 24 8826 BCL11A-7182 - AGAAAAUUUGAAGCCCCC 18 8827 BCL11A-7183 - GAGAAAAUUUGAAGCCCCC 19 8828 BCL11A-5969 - UGAGAAAAUUUGAAGCCCCC 20 8829 BCL11A-7184 - CUGAGAAAAUUUGAAGCCCCC 21 8830 BCL11A-7185 - UCUGAGAAAAUUUGAAGCCCCC 22 8831 BCL11A-7186 - UUCUGAGAAAAUUUGAAGCCCCC 23 8832 BCL11A-7187 - GUUCUGAGAAAAUUUGAAGCCCCC 24 8833 BCL11A-7188 - GCUAUGGAGCCUCCCGCC 18 8834 BCL11A-7189 - GGCUAUGGAGCCUCCCGCC 19 8835 BCL11A-7190 - UGGCUAUGGAGCCUCCCGCC 20 8836 BCL11A-7191 - AUGGCUAUGGAGCCUCCCGCC 21 8837 BCL11A-7192 - AAUGGCUAUGGAGCCUCCCGCC 22 8838 BCL11A-7193 - CAAUGGCUAUGGAGCCUCCCGCC 23 8839 BCL11A-7194 - CCAAUGGCUAUGGAGCCUCCCGCC 24 8840 BCL11A-7195 - AACACGCACAGAACACUC 18 8841 BCL11A-7196 - CAACACGCACAGAACACUC 19 8842 BCL11A-7197 - GCAACACGCACAGAACACUC 20 8843 BCL11A-7198 - UGCAACACGCACAGAACACUC 21 8844 BCL11A-7199 - UUGCAACACGCACAGAACACUC 22 8845 BCL11A-7200 - CUUGCAACACGCACAGAACACUC 23 8846 BCL11A-7201 - UCUUGCAACACGCACAGAACACUC 24 8847 BCL11A-7202 - ACGAAGACUCGGUGGCCG 18 8848 BCL11A-7203 - GACGAAGACUCGGUGGCCG 19 8849 BCL11A-7204 - CGACGAAGACUCGGUGGCCG 20 8850 BCL11A-7205 - GCGACGAAGACUCGGUGGCCG 21 8851 BCL11A-7206 - UGCGACGAAGACUCGGUGGCCG 22 8852 BCL11A-7207 - UUGCGACGAAGACUCGGUGGCCG 23 8853 BCL11A-7208 - CUUGCGACGAAGACUCGGUGGCCG 24 8854 BCL11A-7209 - GCCCGGGGAGCUGGACGG 18 8855 BCL11A-7210 - CGCCCGGGGAGCUGGACGG 19 8856 BCL11A-6121 - CCGCCCGGGGAGCUGGACGG 20 8857 BCL11A-7211 - ACCGCCCGGGGAGCUGGACGG 21 8858 BCL11A-7212 - CACCGCCCGGGGAGCUGGACGG 22 8859 BCL11A-7213 - ACACCGCCCGGGGAGCUGGACGG 23 8860 BCL11A-7214 - CACACCGCCCGGGGAGCUGGACGG 24 8861 BCL11A-7215 - GCCGCGGCUGCUCCCCGG 18 8862 BCL11A-7216 - GGCCGCGGCUGCUCCCCGG 19 8863 BCL11A-7217 - UGGCCGCGGCUGCUCCCCGG 20 8864 BCL11A-7218 - AUGGCCGCGGCUGCUCCCCGG 21 8865 BCL11A-7219 - AAUGGCCGCGGCUGCUCCCCGG 22 8866 BCL11A-7220 - UAAUGGCCGCGGCUGCUCCCCGG 23 8867 BCL11A-7221 - UUAAUGGCCGCGGCUGCUCCCCGG 24 8868 BCL11A-7222 - UUUGACAGGGUGCUGCGG 18 8869 BCL11A-7223 - CUUUGACAGGGUGCUGCGG 19 8870 BCL11A-7224 - CCUUUGACAGGGUGCUGCGG 20 8871 BCL11A-7225 - GCCUUUGACAGGGUGCUGCGG 21 8872 BCL11A-7226 - UGCCUUUGACAGGGUGCUGCGG 22 8873 BCL11A-7227 - GUGCCUUUGACAGGGUGCUGCGG 23 8874 BCL11A-7228 - AGUGCCUUUGACAGGGUGCUGCGG 24 8875 BCL11A-7229 - AUUUGAAGCCCCCAGGGG 18 8876 BCL11A-7230 - AAUUUGAAGCCCCCAGGGG 19 8877 BCL11A-6140 - AAAUUUGAAGCCCCCAGGGG 20 8878 BCL11A-7231 - AAAAUUUGAAGCCCCCAGGGG 21 8879 BCL11A-7232 - GAAAAUUUGAAGCCCCCAGGGG 22 8880 BCL11A-7233 - AGAAAAUUUGAAGCCCCCAGGGG 23 8881 BCL11A-7234 - GAGAAAAUUUGAAGCCCCCAGGGG 24 8882 BCL11A-7235 - UCCCUUCAGGACUAGGUG 18 8883 BCL11A-7236 - AUCCCUUCAGGACUAGGUG 19 8884 BCL11A-7237 - UAUCCCUUCAGGACUAGGUG 20 8885 BCL11A-7238 - GUAUCCCUUCAGGACUAGGUG 21 8886 BCL11A-7239 - GGUAUCCCUUCAGGACUAGGUG 22 8887 BCL11A-7240 - UGGUAUCCCUUCAGGACUAGGUG 23 8888 BCL11A-7241 - UUGGUAUCCCUUCAGGACUAGGUG 24 8889 BCL11A-7242 - CGGUCAAGUCCAAGUCAU 18 8890 BCL11A-7243 - CCGGUCAAGUCCAAGUCAU 19 8891 BCL11A-7244 - CCCGGUCAAGUCCAAGUCAU 20 8892 BCL11A-7245 - CCCCGGUCAAGUCCAAGUCAU 21 8893 BCL11A-7246 - CCCCCGGUCAAGUCCAAGUCAU 22 8894 BCL11A-7247 - GCCCCCGGUCAAGUCCAAGUCAU 23 8895 BCL11A-7248 - AGCCCCCGGUCAAGUCCAAGUCAU 24 8896 BCL11A-7249 - UAACCCCUUUAACCUGCU 18 8897 BCL11A-7250 - AUAACCCCUUUAACCUGCU 19 8898 BCL11A-7251 - AAUAACCCCUUUAACCUGCU 20 8899 BCL11A-7252 - CAAUAACCCCUUUAACCUGCU 21 8900 BCL11A-7253 - ACAAUAACCCCUUUAACCUGCU 22 8901 BCL11A-7254 - GACAAUAACCCCUUUAACCUGCU 23 8902 BCL11A-7255 - AGACAAUAACCCCUUUAACCUGCU 24 8903 BCL11A-7256 - ACAGAACACUCAUGGAUU 18 8904 BCL11A-7257 - CACAGAACACUCAUGGAUU 19 8905 BCL11A-7258 - GCACAGAACACUCAUGGAUU 20 8906 BCL11A-7259 - CGCACAGAACACUCAUGGAUU 21 8907 BCL11A-7260 - ACGCACAGAACACUCAUGGAUU 22 8908 BCL11A-7261 - CACGCACAGAACACUCAUGGAUU 23 8909 BCL11A-7262 - ACACGCACAGAACACUCAUGGAUU 24 8910 BCL11A-7263 - GCAGACGCAGCGACACUU 18 8911 BCL11A-7264 - GGCAGACGCAGCGACACUU 19 8912 BCL11A-7265 - GGGCAGACGCAGCGACACUU 20 8913 BCL11A-7266 - AGGGCAGACGCAGCGACACUU 21 8914 BCL11A-7267 - GAGGGCAGACGCAGCGACACUU 22 8915 BCL11A-7268 - AGAGGGCAGACGCAGCGACACUU 23 8916 BCL11A-7269 - AAGAGGGCAGACGCAGCGACACUU 24 8917 BCL11A-7270 - CAAGAUGUGUGGCAGUUU 18 8918 BCL11A-7271 - UCAAGAUGUGUGGCAGUUU 19 8919 BCL11A-7272 - CUCAAGAUGUGUGGCAGUUU 20 8920 BCL11A-7273 - GCUCAAGAUGUGUGGCAGUUU 21 8921 BCL11A-7274 - AGCUCAAGAUGUGUGGCAGUUU 22 8922 BCL11A-7275 - GAGCUCAAGAUGUGUGGCAGUUU 23 8923 BCL11A-7276 - AGAGCUCAAGAUGUGUGGCAGUUU 24 8924

Table 16E provides exemplary targeting domains for knocking out the BCL11A gene selected according to the fifth tier parameters. The targeting domains fall in the coding sequence of the gene, downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon of the gene), and the PAM is NNGRRV. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 16E 5th Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-7277 + UCUCGGUGGUGGACUAAA 18 8925 BCL11A-7278 + GUCUCGGUGGUGGACUAAA 19 8926 BCL11A-7279 + UGUCUCGGUGGUGGACUAAA 20 8927 BCL11A-7280 + AUGUCUCGGUGGUGGACUAAA 21 8928 BCL11A-7281 + GAUGUCUCGGUGGUGGACUAAA 22 8929 BCL11A-7282 + UGAUGUCUCGGUGGUGGACUAAA 23 8930 BCL11A-7283 + GUGAUGUCUCGGUGGUGGACUAAA 24 8931 BCL11A-7284 + GUUCUGUGCGUGUUGCAA 18 8932 BCL11A-7285 + UGUUCUGUGCGUGUUGCAA 19 8933 BCL11A-7286 + GUGUUCUGUGCGUGUUGCAA 20 8934 BCL11A-7287 + AGUGUUCUGUGCGUGUUGCAA 21 8935 BCL11A-7288 + GAGUGUUCUGUGCGUGUUGCAA 22 8936 BCL11A-7289 + UGAGUGUUCUGUGCGUGUUGCAA 23 8937 BCL11A-7290 + AUGAGUGUUCUGUGCGUGUUGCAA 24 8938 BCL11A-7291 + UCUGGGUACUACGCCGAA 18 8939 BCL11A-7292 + CUCUGGGUACUACGCCGAA 19 8940 BCL11A-5883 + UCUCUGGGUACUACGCCGAA 20 8941 BCL11A-7293 + CUCUCUGGGUACUACGCCGAA 21 8942 BCL11A-7294 + GCUCUCUGGGUACUACGCCGAA 22 8943 BCL11A-7295 + AGCUCUCUGGGUACUACGCCGAA 23 8944 BCL11A-7296 + GAGCUCUCUGGGUACUACGCCGAA 24 8945 BCL11A-7297 + UCGGUGGUGGACUAAACA 18 8946 BCL11A-7298 + CUCGGUGGUGGACUAAACA 19 8947 BCL11A-5892 + UCUCGGUGGUGGACUAAACA 20 8948 BCL11A-7299 + GUCUCGGUGGUGGACUAAACA 21 8949 BCL11A-7300 + UGUCUCGGUGGUGGACUAAACA 22 8950 BCL11A-7301 + AUGUCUCGGUGGUGGACUAAACA 23 8951 BCL11A-7302 + GAUGUCUCGGUGGUGGACUAAACA 24 8952 BCL11A-7303 + AGAAAGAGGUUGGAGACA 18 8953 BCL11A-7304 + UAGAAAGAGGUUGGAGACA 19 8954 BCL11A-7305 + CUAGAAAGAGGUUGGAGACA 20 8955 BCL11A-7306 + CCUAGAAAGAGGUUGGAGACA 21 8956 BCL11A-7307 + ACCUAGAAAGAGGUUGGAGACA 22 8957 BCL11A-7308 + AACCUAGAAAGAGGUUGGAGACA 23 8958 BCL11A-7309 + GAACCUAGAAAGAGGUUGGAGACA 24 8959 BCL11A-7310 + UCUGCAAUAUGAAUCCCA 18 8960 BCL11A-7311 + GUCUGCAAUAUGAAUCCCA 19 8961 BCL11A-5899 + UGUCUGCAAUAUGAAUCCCA 20 8962 BCL11A-7312 + UUGUCUGCAAUAUGAAUCCCA 21 8963 BCL11A-7313 + AUUGUCUGCAAUAUGAAUCCCA 22 8964 BCL11A-7314 + UAUUGUCUGCAAUAUGAAUCCCA 23 8965 BCL11A-7315 + UUAUUGUCUGCAAUAUGAAUCCCA 24 8966 BCL11A-7316 + CCUCGCUGAAGUGCUGCA 18 8967 BCL11A-7317 + GCCUCGCUGAAGUGCUGCA 19 8968 BCL11A-5909 + GGCCUCGCUGAAGUGCUGCA 20 8969 BCL11A-7318 + AGGCCUCGCUGAAGUGCUGCA 21 8970 BCL11A-7319 + AAGGCCUCGCUGAAGUGCUGCA 22 8971 BCL11A-7320 + GAAGGCCUCGCUGAAGUGCUGCA 23 8972 BCL11A-7321 + GGAAGGCCUCGCUGAAGUGCUGCA 24 8973 BCL11A-7322 + GAGGAGGGGCGGAUUGCA 18 8974 BCL11A-7323 + GGAGGAGGGGCGGAUUGCA 19 8975 BCL11A-7324 + GGGAGGAGGGGCGGAUUGCA 20 8976 BCL11A-7325 + AGGGAGGAGGGGCGGAUUGCA 21 8977 BCL11A-7326 + GAGGGAGGAGGGGCGGAUUGCA 22 8978 BCL11A-7327 + GGAGGGAGGAGGGGCGGAUUGCA 23 8979 BCL11A-7328 + GGGAGGGAGGAGGGGCGGAUUGCA 24 8980 BCL11A-7329 + GUUGCAGUAACCUUUGCA 18 8981 BCL11A-7330 + GGUUGCAGUAACCUUUGCA 19 8982 BCL11A-7331 + UGGUUGCAGUAACCUUUGCA 20 8983 BCL11A-7332 + AUGGUUGCAGUAACCUUUGCA 21 8984 BCL11A-7333 + AAUGGUUGCAGUAACCUUUGCA 22 8985 BCL11A-7334 + GAAUGGUUGCAGUAACCUUUGCA 23 8986 BCL11A-7335 + GGAAUGGUUGCAGUAACCUUUGCA 24 8987 BCL11A-7336 + GCUUAGAGAAGGGGCUCA 18 8988 BCL11A-7337 + CGCUUAGAGAAGGGGCUCA 19 8989 BCL11A-7338 + GCGCUUAGAGAAGGGGCUCA 20 8990 BCL11A-7339 + UGCGCUUAGAGAAGGGGCUCA 21 8991 BCL11A-7340 + AUGCGCUUAGAGAAGGGGCUCA 22 8992 BCL11A-7341 + GAUGCGCUUAGAGAAGGGGCUCA 23 8993 BCL11A-7342 + UGAUGCGCUUAGAGAAGGGGCUCA 24 8994 BCL11A-7343 + CGUCGGACUUGACCGUCA 18 8995 BCL11A-7344 + UCGUCGGACUUGACCGUCA 19 8996 BCL11A-5912 + GUCGUCGGACUUGACCGUCA 20 8997 BCL11A-7345 + CGUCGUCGGACUUGACCGUCA 21 8998 BCL11A-7346 + CCGUCGUCGGACUUGACCGUCA 22 8999 BCL11A-7347 + ACCGUCGUCGGACUUGACCGUCA 23 9000 BCL11A-7348 + GACCGUCGUCGGACUUGACCGUCA 24 9001 BCL11A-7349 + UACCAACCCGCGGGGUCA 18 9002 BCL11A-7350 + AUACCAACCCGCGGGGUCA 19 9003 BCL11A-5913 + GAUACCAACCCGCGGGGUCA 20 9004 BCL11A-7351 + GGAUACCAACCCGCGGGGUCA 21 9005 BCL11A-7352 + GGGAUACCAACCCGCGGGGUCA 22 9006 BCL11A-7353 + AGGGAUACCAACCCGCGGGGUCA 23 9007 BCL11A-7354 + AAGGGAUACCAACCCGCGGGGUCA 24 9008 BCL11A-7355 + GCUUGAUGCGCUUAGAGA 18 9009 BCL11A-7356 + AGCUUGAUGCGCUUAGAGA 19 9010 BCL11A-5917 + GAGCUUGAUGCGCUUAGAGA 20 9011 BCL11A-7357 + CGAGCUUGAUGCGCUUAGAGA 21 9012 BCL11A-7358 + UCGAGCUUGAUGCGCUUAGAGA 22 9013 BCL11A-7359 + CUCGAGCUUGAUGCGCUUAGAGA 23 9014 BCL11A-7360 + UCUCGAGCUUGAUGCGCUUAGAGA 24 9015 BCL11A-7361 + CUAGAAAGAGGUUGGAGA 18 9016 BCL11A-7362 + CCUAGAAAGAGGUUGGAGA 19 9017 BCL11A-7363 + ACCUAGAAAGAGGUUGGAGA 20 9018 BCL11A-7364 + AACCUAGAAAGAGGUUGGAGA 21 9019 BCL11A-7365 + GAACCUAGAAAGAGGUUGGAGA 22 9020 BCL11A-7366 + AGAACCUAGAAAGAGGUUGGAGA 23 9021 BCL11A-7367 + AAGAACCUAGAAAGAGGUUGGAGA 24 9022 BCL11A-7368 + GUGUGUGAAGAACCUAGA 18 9023 BCL11A-7369 + GGUGUGUGAAGAACCUAGA 19 9024 BCL11A-7370 + GGGUGUGUGAAGAACCUAGA 20 9025 BCL11A-7371 + GGGGUGUGUGAAGAACCUAGA 21 9026 BCL11A-7372 + GGGGGUGUGUGAAGAACCUAGA 22 9027 BCL11A-7373 + UGGGGGUGUGUGAAGAACCUAGA 23 9028 BCL11A-7374 + AUGGGGGUGUGUGAAGAACCUAGA 24 9029 BCL11A-7375 + CUCUGGGUACUACGCCGA 18 9030 BCL11A-7376 + UCUCUGGGUACUACGCCGA 19 9031 BCL11A-7377 + CUCUCUGGGUACUACGCCGA 20 9032 BCL11A-7378 + GCUCUCUGGGUACUACGCCGA 21 9033 BCL11A-7379 + AGCUCUCUGGGUACUACGCCGA 22 9034 BCL11A-7380 + GAGCUCUCUGGGUACUACGCCGA 23 9035 BCL11A-7381 + UGAGCUCUCUGGGUACUACGCCGA 24 9036 BCL11A-7382 + GAGGUUGGAGACAGAGGA 18 9037 BCL11A-7383 + AGAGGUUGGAGACAGAGGA 19 9038 BCL11A-5925 + AAGAGGUUGGAGACAGAGGA 20 9039 BCL11A-7384 + AAAGAGGUUGGAGACAGAGGA 21 9040 BCL11A-7385 + GAAAGAGGUUGGAGACAGAGGA 22 9041 BCL11A-7386 + AGAAAGAGGUUGGAGACAGAGGA 23 9042 BCL11A-7387 + UAGAAAGAGGUUGGAGACAGAGGA 24 9043 BCL11A-7388 + GGGGCGGAUUGCAGAGGA 18 9044 BCL11A-7389 + AGGGGCGGAUUGCAGAGGA 19 9045 BCL11A-5926 + GAGGGGCGGAUUGCAGAGGA 20 9046 BCL11A-7390 + GGAGGGGCGGAUUGCAGAGGA 21 9047 BCL11A-7391 + AGGAGGGGCGGAUUGCAGAGGA 22 9048 BCL11A-7392 + GAGGAGGGGCGGAUUGCAGAGGA 23 9049 BCL11A-7393 + GGAGGAGGGGCGGAUUGCAGAGGA 24 9050 BCL11A-7394 + CGGAUUGCAGAGGAGGGA 18 9051 BCL11A-7395 + GCGGAUUGCAGAGGAGGGA 19 9052 BCL11A-5930 + GGCGGAUUGCAGAGGAGGGA 20 9053 BCL11A-7396 + GGGCGGAUUGCAGAGGAGGGA 21 9054 BCL11A-7397 + GGGGCGGAUUGCAGAGGAGGGA 22 9055 BCL11A-7398 + AGGGGCGGAUUGCAGAGGAGGGA 23 9056 BCL11A-7399 + GAGGGGCGGAUUGCAGAGGAGGGA 24 9057 BCL11A-7400 + CUUGACCGGGGGCUGGGA 18 9058 BCL11A-7401 + ACUUGACCGGGGGCUGGGA 19 9059 BCL11A-5931 + GACUUGACCGGGGGCUGGGA 20 9060 BCL11A-7402 + GGACUUGACCGGGGGCUGGGA 21 9061 BCL11A-7403 + UGGACUUGACCGGGGGCUGGGA 22 9062 BCL11A-7404 + UUGGACUUGACCGGGGGCUGGGA 23 9063 BCL11A-7405 + CUUGGACUUGACCGGGGGCUGGGA 24 9064 BCL11A-7406 + CGCAUGACUUGGACUUGA 18 9065 BCL11A-7407 + UCGCAUGACUUGGACUUGA 19 9066 BCL11A-7408 + CUCGCAUGACUUGGACUUGA 20 9067 BCL11A-7409 + ACUCGCAUGACUUGGACUUGA 21 9068 BCL11A-7410 + AACUCGCAUGACUUGGACUUGA 22 9069 BCL11A-7411 + GAACUCGCAUGACUUGGACUUGA 23 9070 BCL11A-7412 + AGAACUCGCAUGACUUGGACUUGA 24 9071 BCL11A-7413 + GGGCCCGGACCACUAAUA 18 9072 BCL11A-7414 + CGGGCCCGGACCACUAAUA 19 9073 BCL11A-5940 + CCGGGCCCGGACCACUAAUA 20 9074 BCL11A-7415 + CCCGGGCCCGGACCACUAAUA 21 9075 BCL11A-7416 + GCCCGGGCCCGGACCACUAAUA 22 9076 BCL11A-7417 + UGCCCGGGCCCGGACCACUAAUA 23 9077 BCL11A-7418 + CUGCCCGGGCCCGGACCACUAAUA 24 9078 BCL11A-7419 + AGCUCUCUAAGUCUCCUA 18 9079 BCL11A-7420 + CAGCUCUCUAAGUCUCCUA 19 9080 BCL11A-7421 + CCAGCUCUCUAAGUCUCCUA 20 9081 BCL11A-7422 + GCCAGCUCUCUAAGUCUCCUA 21 9082 BCL11A-7423 + UGCCAGCUCUCUAAGUCUCCUA 22 9083 BCL11A-7424 + CUGCCAGCUCUCUAAGUCUCCUA 23 9084 BCL11A-7425 + CCUGCCAGCUCUCUAAGUCUCCUA 24 9085 BCL11A-7426 + CUGGAGUCUCCGAAGCUA 18 9086 BCL11A-7427 + UCUGGAGUCUCCGAAGCUA 19 9087 BCL11A-5943 + GUCUGGAGUCUCCGAAGCUA 20 9088 BCL11A-7428 + UGUCUGGAGUCUCCGAAGCUA 21 9089 BCL11A-7429 + UUGUCUGGAGUCUCCGAAGCUA 22 9090 BCL11A-7430 + AUUGUCUGGAGUCUCCGAAGCUA 23 9091 BCL11A-7431 + GAUUGUCUGGAGUCUCCGAAGCUA 24 9092 BCL11A-7432 + UCGAGCUUGAUGCGCUUA 18 9093 BCL11A-7433 + CUCGAGCUUGAUGCGCUUA 19 9094 BCL11A-7434 + UCUCGAGCUUGAUGCGCUUA 20 9095 BCL11A-7435 + UUCUCGAGCUUGAUGCGCUUA 21 9096 BCL11A-7436 + CUUCUCGAGCUUGAUGCGCUUA 22 9097 BCL11A-7437 + CCUUCUCGAGCUUGAUGCGCUUA 23 9098 BCL11A-7438 + UCCUUCUCGAGCUUGAUGCGCUUA 24 9099 BCL11A-7439 + GGUAUUCUUAGCAGGUUA 18 9100 BCL11A-7440 + UGGUAUUCUUAGCAGGUUA 19 9101 BCL11A-7441 + CUGGUAUUCUUAGCAGGUUA 20 9102 BCL11A-7442 + CCUGGUAUUCUUAGCAGGUUA 21 9103 BCL11A-7443 + UCCUGGUAUUCUUAGCAGGUUA 22 9104 BCL11A-7444 + AUCCUGGUAUUCUUAGCAGGUUA 23 9105 BCL11A-7445 + GAUCCUGGUAUUCUUAGCAGGUUA 24 9106 BCL11A-7446 + CUCGGUGGUGGACUAAAC 18 9107 BCL11A-7447 + UCUCGGUGGUGGACUAAAC 19 9108 BCL11A-5947 + GUCUCGGUGGUGGACUAAAC 20 9109 BCL11A-7448 + UGUCUCGGUGGUGGACUAAAC 21 9110 BCL11A-7449 + AUGUCUCGGUGGUGGACUAAAC 22 9111 BCL11A-7450 + GAUGUCUCGGUGGUGGACUAAAC 23 9112 BCL11A-7451 + UGAUGUCUCGGUGGUGGACUAAAC 24 9113 BCL11A-7452 + UCCGAGGAGUGCUCCGAC 18 9114 BCL11A-7453 + CUCCGAGGAGUGCUCCGAC 19 9115 BCL11A-7454 + UCUCCGAGGAGUGCUCCGAC 20 9116 BCL11A-7455 + UUCUCCGAGGAGUGCUCCGAC 21 9117 BCL11A-7456 + GUUCUCCGAGGAGUGCUCCGAC 22 9118 BCL11A-7457 + CGUUCUCCGAGGAGUGCUCCGAC 23 9119 BCL11A-7458 + CCGUUCUCCGAGGAGUGCUCCGAC 24 9120 BCL11A-7459 + AACUUGGCCACCACGGAC 18 9121 BCL11A-7460 + GAACUUGGCCACCACGGAC 19 9122 BCL11A-7461 + UGAACUUGGCCACCACGGAC 20 9123 BCL11A-7462 + UUGAACUUGGCCACCACGGAC 21 9124 BCL11A-7463 + CUUGAACUUGGCCACCACGGAC 22 9125 BCL11A-7464 + UCUUGAACUUGGCCACCACGGAC 23 9126 BCL11A-7465 + CUCUUGAACUUGGCCACCACGGAC 24 9127 BCL11A-7466 + CCGCAGAACUCGCAUGAC 18 9128 BCL11A-7467 + GCCGCAGAACUCGCAUGAC 19 9129 BCL11A-7468 + UGCCGCAGAACUCGCAUGAC 20 9130 BCL11A-7469 + UUGCCGCAGAACUCGCAUGAC 21 9131 BCL11A-7470 + CUUGCCGCAGAACUCGCAUGAC 22 9132 BCL11A-7471 + UCUUGCCGCAGAACUCGCAUGAC 23 9133 BCL11A-7472 + GUCUUGCCGCAGAACUCGCAUGAC 24 9134 BCL11A-7473 + GCAUGACUUGGACUUGAC 18 9135 BCL11A-7474 + CGCAUGACUUGGACUUGAC 19 9136 BCL11A-5957 + UCGCAUGACUUGGACUUGAC 20 9137 BCL11A-7475 + CUCGCAUGACUUGGACUUGAC 21 9138 BCL11A-7476 + ACUCGCAUGACUUGGACUUGAC 22 9139 BCL11A-7477 + AACUCGCAUGACUUGGACUUGAC 23 9140 BCL11A-7478 + GAACUCGCAUGACUUGGACUUGAC 24 9141 BCL11A-7479 + GGGGGUGUGUGAAGAACC 18 9142 BCL11A-7480 + UGGGGGUGUGUGAAGAACC 19 9143 BCL11A-7481 + AUGGGGGUGUGUGAAGAACC 20 9144 BCL11A-7482 + AAUGGGGGUGUGUGAAGAACC 21 9145 BCL11A-7483 + GAAUGGGGGUGUGUGAAGAACC 22 9146 BCL11A-7484 + CGAAUGGGGGUGUGUGAAGAACC 23 9147 BCL11A-7485 + CCGAAUGGGGGUGUGUGAAGAACC 24 9148 BCL11A-7486 + CUCUUGAACUUGGCCACC 18 9149 BCL11A-7487 + GCUCUUGAACUUGGCCACC 19 9150 BCL11A-7488 + CGCUCUUGAACUUGGCCACC 20 9151 BCL11A-7489 + UCGCUCUUGAACUUGGCCACC 21 9152 BCL11A-7490 + CUCGCUCUUGAACUUGGCCACC 22 9153 BCL11A-7491 + UCUCGCUCUUGAACUUGGCCACC 23 9154 BCL11A-7492 + UUCUCGCUCUUGAACUUGGCCACC 24 9155 BCL11A-7493 + CAUGACUUGGACUUGACC 18 9156 BCL11A-7494 + GCAUGACUUGGACUUGACC 19 9157 BCL11A-5965 + CGCAUGACUUGGACUUGACC 20 9158 BCL11A-7495 + UCGCAUGACUUGGACUUGACC 21 9159 BCL11A-7496 + CUCGCAUGACUUGGACUUGACC 22 9160 BCL11A-7497 + ACUCGCAUGACUUGGACUUGACC 23 9161 BCL11A-7498 + AACUCGCAUGACUUGGACUUGACC 24 9162 BCL11A-7499 + CUGAAGGGAUACCAACCC 18 9163 BCL11A-7500 + CCUGAAGGGAUACCAACCC 19 9164 BCL11A-7501 + UCCUGAAGGGAUACCAACCC 20 9165 BCL11A-7502 + GUCCUGAAGGGAUACCAACCC 21 9166 BCL11A-7503 + AGUCCUGAAGGGAUACCAACCC 22 9167 BCL11A-7504 + UAGUCCUGAAGGGAUACCAACCC 23 9168 BCL11A-7505 + CUAGUCCUGAAGGGAUACCAACCC 24 9169 BCL11A-7506 + CGCCCACGACCGCGCCCC 18 9170 BCL11A-7507 + ACGCCCACGACCGCGCCCC 19 9171 BCL11A-3830 + CACGCCCACGACCGCGCCCC 20 9172 BCL11A-7508 + CCACGCCCACGACCGCGCCCC 21 9173 BCL11A-7509 + CCCACGCCCACGACCGCGCCCC 22 9174 BCL11A-7510 + GCCCACGCCCACGACCGCGCCCC 23 9175 BCL11A-7511 + CGCCCACGCCCACGACCGCGCCCC 24 9176 BCL11A-7512 + GCUUUUUGGACAGGCCCC 18 9177 BCL11A-7513 + AGCUUUUUGGACAGGCCCC 19 9178 BCL11A-7514 + CAGCUUUUUGGACAGGCCCC 20 9179 BCL11A-7515 + GCAGCUUUUUGGACAGGCCCC 21 9180 BCL11A-7516 + AGCAGCUUUUUGGACAGGCCCC 22 9181 BCL11A-7517 + CAGCAGCUUUUUGGACAGGCCCC 23 9182 BCL11A-7518 + GCAGCAGCUUUUUGGACAGGCCCC 24 9183 BCL11A-7519 + CCCGAGGCCGACUCGCCC 18 9184 BCL11A-7520 + CCCCGAGGCCGACUCGCCC 19 9185 BCL11A-5977 + CCCCCGAGGCCGACUCGCCC 20 9186 BCL11A-7521 + CCCCCCGAGGCCGACUCGCCC 21 9187 BCL11A-7522 + GCCCCCCGAGGCCGACUCGCCC 22 9188 BCL11A-7523 + GGCCCCCCGAGGCCGACUCGCCC 23 9189 BCL11A-7524 + AGGCCCCCCGAGGCCGACUCGCCC 24 9190 BCL11A-7525 + GUCUGCAAUAUGAAUCCC 18 9191 BCL11A-7526 + UGUCUGCAAUAUGAAUCCC 19 9192 BCL11A-7527 + UUGUCUGCAAUAUGAAUCCC 20 9193 BCL11A-7528 + AUUGUCUGCAAUAUGAAUCCC 21 9194 BCL11A-7529 + UAUUGUCUGCAAUAUGAAUCCC 22 9195 BCL11A-7530 + UUAUUGUCUGCAAUAUGAAUCCC 23 9196 BCL11A-7531 + GUUAUUGUCUGCAAUAUGAAUCCC 24 9197 BCL11A-7532 + UUCCCGUGCCGCUGCGCC 18 9198 BCL11A-7533 + CUUCCCGUGCCGCUGCGCC 19 9199 BCL11A-7534 + ACUUCCCGUGCCGCUGCGCC 20 9200 BCL11A-7535 + CACUUCCCGUGCCGCUGCGCC 21 9201 BCL11A-7536 + CCACUUCCCGUGCCGCUGCGCC 22 9202 BCL11A-7537 + UCCACUUCCCGUGCCGCUGCGCC 23 9203 BCL11A-7538 + CUCCACUUCCCGUGCCGCUGCGCC 24 9204 BCL11A-7539 + CCCCGAGGCCGACUCGCC 18 9205 BCL11A-7540 + CCCCCGAGGCCGACUCGCC 19 9206 BCL11A-5989 + CCCCCCGAGGCCGACUCGCC 20 9207 BCL11A-7541 + GCCCCCCGAGGCCGACUCGCC 21 9208 BCL11A-7542 + GGCCCCCCGAGGCCGACUCGCC 22 9209 BCL11A-7543 + AGGCCCCCCGAGGCCGACUCGCC 23 9210 BCL11A-7544 + CAGGCCCCCCGAGGCCGACUCGCC 24 9211 BCL11A-7545 + GCGCUUAUGCUUCUCGCC 18 9212 BCL11A-7546 + CGCGCUUAUGCUUCUCGCC 19 9213 BCL11A-7547 + CCGCGCUUAUGCUUCUCGCC 20 9214 BCL11A-7548 + GCCGCGCUUAUGCUUCUCGCC 21 9215 BCL11A-7549 + GGCCGCGCUUAUGCUUCUCGCC 22 9216 BCL11A-7550 + UGGCCGCGCUUAUGCUUCUCGCC 23 9217 BCL11A-7551 + GUGGCCGCGCUUAUGCUUCUCGCC 24 9218 BCL11A-7552 + GGGAGGGGGGGCGUCGCC 18 9219 BCL11A-7553 + AGGGAGGGGGGGCGUCGCC 19 9220 BCL11A-5990 + GAGGGAGGGGGGGCGUCGCC 20 9221 BCL11A-7554 + GGAGGGAGGGGGGGCGUCGCC 21 9222 BCL11A-7555 + AGGAGGGAGGGGGGGCGUCGCC 22 9223 BCL11A-7556 + GAGGAGGGAGGGGGGGCGUCGCC 23 9224 BCL11A-7557 + AGAGGAGGGAGGGGGGGCGUCGCC 24 9225 BCL11A-7558 + CAUAGGGCUGGGCCGGCC 18 9226 BCL11A-7559 + GCAUAGGGCUGGGCCGGCC 19 9227 BCL11A-5991 + UGCAUAGGGCUGGGCCGGCC 20 9228 BCL11A-7560 + UUGCAUAGGGCUGGGCCGGCC 21 9229 BCL11A-7561 + UUUGCAUAGGGCUGGGCCGGCC 22 9230 BCL11A-7562 + CUUUGCAUAGGGCUGGGCCGGCC 23 9231 BCL11A-7563 + CCUUUGCAUAGGGCUGGGCCGGCC 24 9232 BCL11A-7564 + GUGUUGGGCAUCGCGGCC 18 9233 BCL11A-7565 + CGUGUUGGGCAUCGCGGCC 19 9234 BCL11A-5993 + CCGUGUUGGGCAUCGCGGCC 20 9235 BCL11A-7566 + UCCGUGUUGGGCAUCGCGGCC 21 9236 BCL11A-7567 + CUCCGUGUUGGGCAUCGCGGCC 22 9237 BCL11A-7568 + UCUCCGUGUUGGGCAUCGCGGCC 23 9238 BCL11A-7569 + UUCUCCGUGUUGGGCAUCGCGGCC 24 9239 BCL11A-7570 + AGGGAUCUUUGAGCUGCC 18 9240 BCL11A-7571 + AAGGGAUCUUUGAGCUGCC 19 9241 BCL11A-6000 + GAAGGGAUCUUUGAGCUGCC 20 9242 BCL11A-7572 + GGAAGGGAUCUUUGAGCUGCC 21 9243 BCL11A-7573 + AGGAAGGGAUCUUUGAGCUGCC 22 9244 BCL11A-7574 + AAGGAAGGGAUCUUUGAGCUGCC 23 9245 BCL11A-7575 + UAAGGAAGGGAUCUUUGAGCUGCC 24 9246 BCL11A-7576 + AUCCCUCCGUCCAGCUCC 18 9247 BCL11A-7577 + GAUCCCUCCGUCCAGCUCC 19 9248 BCL11A-7578 + AGAUCCCUCCGUCCAGCUCC 20 9249 BCL11A-7579 + GAGAUCCCUCCGUCCAGCUCC 21 9250 BCL11A-7580 + CGAGAUCCCUCCGUCCAGCUCC 22 9251 BCL11A-7581 + CCGAGAUCCCUCCGUCCAGCUCC 23 9252 BCL11A-7582 + CCCGAGAUCCCUCCGUCCAGCUCC 24 9253 BCL11A-7583 + CCAGCUCUCUAAGUCUCC 18 9254 BCL11A-7584 + GCCAGCUCUCUAAGUCUCC 19 9255 BCL11A-7585 + UGCCAGCUCUCUAAGUCUCC 20 9256 BCL11A-7586 + CUGCCAGCUCUCUAAGUCUCC 21 9257 BCL11A-7587 + CCUGCCAGCUCUCUAAGUCUCC 22 9258 BCL11A-7588 + CCCUGCCAGCUCUCUAAGUCUCC 23 9259 BCL11A-7589 + UCCCUGCCAGCUCUCUAAGUCUCC 24 9260 BCL11A-7590 + CGCAAACUCCCGUUCUCC 18 9261 BCL11A-7591 + GCGCAAACUCCCGUUCUCC 19 9262 BCL11A-7592 + AGCGCAAACUCCCGUUCUCC 20 9263 BCL11A-7593 + AAGCGCAAACUCCCGUUCUCC 21 9264 BCL11A-7594 + GAAGCGCAAACUCCCGUUCUCC 22 9265 BCL11A-7595 + AGAAGCGCAAACUCCCGUUCUCC 23 9266 BCL11A-7596 + GAGAAGCGCAAACUCCCGUUCUCC 24 9267 BCL11A-7597 + UCGCUGGUGCCGGGUUCC 18 9268 BCL11A-7598 + GUCGCUGGUGCCGGGUUCC 19 9269 BCL11A-6011 + AGUCGCUGGUGCCGGGUUCC 20 9270 BCL11A-7599 + AAGUCGCUGGUGCCGGGUUCC 21 9271 BCL11A-7600 + CAAGUCGCUGGUGCCGGGUUCC 22 9272 BCL11A-7601 + CCAAGUCGCUGGUGCCGGGUUCC 23 9273 BCL11A-7602 + ACCAAGUCGCUGGUGCCGGGUUCC 24 9274 BCL11A-7603 + GCCGCCUCCAGGCUCAGC 18 9275 BCL11A-7604 + CGCCGCCUCCAGGCUCAGC 19 9276 BCL11A-7605 + GCGCCGCCUCCAGGCUCAGC 20 9277 BCL11A-7606 + CGCGCCGCCUCCAGGCUCAGC 21 9278 BCL11A-7607 + GCGCGCCGCCUCCAGGCUCAGC 22 9279 BCL11A-7608 + GGCGCGCCGCCUCCAGGCUCAGC 23 9280 BCL11A-7609 + UGGCGCGCCGCCUCCAGGCUCAGC 24 9281 BCL11A-7610 + AGAAGGGGCUCAGCGAGC 18 9282 BCL11A-7611 + GAGAAGGGGCUCAGCGAGC 19 9283 BCL11A-6013 + AGAGAAGGGGCUCAGCGAGC 20 9284 BCL11A-7612 + UAGAGAAGGGGCUCAGCGAGC 21 9285 BCL11A-7613 + UUAGAGAAGGGGCUCAGCGAGC 22 9286 BCL11A-7614 + CUUAGAGAAGGGGCUCAGCGAGC 23 9287 BCL11A-7615 + GCUUAGAGAAGGGGCUCAGCGAGC 24 9288 BCL11A-7616 + CCCCCGAGGCCGACUCGC 18 9289 BCL11A-7617 + CCCCCCGAGGCCGACUCGC 19 9290 BCL11A-7618 + GCCCCCCGAGGCCGACUCGC 20 9291 BCL11A-7619 + GGCCCCCCGAGGCCGACUCGC 21 9292 BCL11A-7620 + AGGCCCCCCGAGGCCGACUCGC 22 9293 BCL11A-7621 + CAGGCCCCCCGAGGCCGACUCGC 23 9294 BCL11A-7622 + ACAGGCCCCCCGAGGCCGACUCGC 24 9295 BCL11A-7623 + AGGGAGGGGGGGCGUCGC 18 9296 BCL11A-7624 + GAGGGAGGGGGGGCGUCGC 19 9297 BCL11A-7625 + GGAGGGAGGGGGGGCGUCGC 20 9298 BCL11A-7626 + AGGAGGGAGGGGGGGCGUCGC 21 9299 BCL11A-7627 + GAGGAGGGAGGGGGGGCGUCGC 22 9300 BCL11A-7628 + AGAGGAGGGAGGGGGGGCGUCGC 23 9301 BCL11A-7629 + CAGAGGAGGGAGGGGGGGCGUCGC 24 9302 BCL11A-7630 + AGCGCCCUUCUGCCAGGC 18 9303 BCL11A-7631 + AAGCGCCCUUCUGCCAGGC 19 9304 BCL11A-6027 + AAAGCGCCCUUCUGCCAGGC 20 9305 BCL11A-7632 + GAAAGCGCCCUUCUGCCAGGC 21 9306 BCL11A-7633 + GGAAAGCGCCCUUCUGCCAGGC 22 9307 BCL11A-7634 + UGGAAAGCGCCCUUCUGCCAGGC 23 9308 BCL11A-7635 + GUGGAAAGCGCCCUUCUGCCAGGC 24 9309 BCL11A-7636 + GCAUAGGGCUGGGCCGGC 18 9310 BCL11A-7637 + UGCAUAGGGCUGGGCCGGC 19 9311 BCL11A-7638 + UUGCAUAGGGCUGGGCCGGC 20 9312 BCL11A-7639 + UUUGCAUAGGGCUGGGCCGGC 21 9313 BCL11A-7640 + CUUUGCAUAGGGCUGGGCCGGC 22 9314 BCL11A-7641 + CCUUUGCAUAGGGCUGGGCCGGC 23 9315 BCL11A-7642 + ACCUUUGCAUAGGGCUGGGCCGGC 24 9316 BCL11A-7643 + CGUGUUGGGCAUCGCGGC 18 9317 BCL11A-7644 + CCGUGUUGGGCAUCGCGGC 19 9318 BCL11A-6028 + UCCGUGUUGGGCAUCGCGGC 20 9319 BCL11A-7645 + CUCCGUGUUGGGCAUCGCGGC 21 9320 BCL11A-7646 + UCUCCGUGUUGGGCAUCGCGGC 22 9321 BCL11A-7647 + UUCUCCGUGUUGGGCAUCGCGGC 23 9322 BCL11A-7648 + GUUCUCCGUGUUGGGCAUCGCGGC 24 9323 BCL11A-7649 + AGCUGGGCCUGCCCGGGC 18 9324 BCL11A-7650 + GAGCUGGGCCUGCCCGGGC 19 9325 BCL11A-7651 + UGAGCUGGGCCUGCCCGGGC 20 9326 BCL11A-7652 + UUGAGCUGGGCCUGCCCGGGC 21 9327 BCL11A-7653 + UUUGAGCUGGGCCUGCCCGGGC 22 9328 BCL11A-7654 + UUUUGAGCUGGGCCUGCCCGGGC 23 9329 BCL11A-7655 + CUUUUGAGCUGGGCCUGCCCGGGC 24 9330 BCL11A-7656 + UUGGACUUGACCGGGGGC 18 9331 BCL11A-7657 + CUUGGACUUGACCGGGGGC 19 9332 BCL11A-6032 + ACUUGGACUUGACCGGGGGC 20 9333 BCL11A-7658 + GACUUGGACUUGACCGGGGGC 21 9334 BCL11A-7659 + UGACUUGGACUUGACCGGGGGC 22 9335 BCL11A-7660 + AUGACUUGGACUUGACCGGGGGC 23 9336 BCL11A-7661 + CAUGACUUGGACUUGACCGGGGGC 24 9337 BCL11A-7662 + CCUAGAGAAAUCCAUGGC 18 9338 BCL11A-7663 + UCCUAGAGAAAUCCAUGGC 19 9339 BCL11A-6035 + CUCCUAGAGAAAUCCAUGGC 20 9340 BCL11A-7664 + UCUCCUAGAGAAAUCCAUGGC 21 9341 BCL11A-7665 + GUCUCCUAGAGAAAUCCAUGGC 22 9342 BCL11A-7666 + AGUCUCCUAGAGAAAUCCAUGGC 23 9343 BCL11A-7667 + AAGUCUCCUAGAGAAAUCCAUGGC 24 9344 BCL11A-7668 + AUCCCAUGGAGAGGUGGC 18 9345 BCL11A-7669 + AAUCCCAUGGAGAGGUGGC 19 9346 BCL11A-6038 + GAAUCCCAUGGAGAGGUGGC 20 9347 BCL11A-7670 + UGAAUCCCAUGGAGAGGUGGC 21 9348 BCL11A-7671 + AUGAAUCCCAUGGAGAGGUGGC 22 9349 BCL11A-7672 + UAUGAAUCCCAUGGAGAGGUGGC 23 9350 BCL11A-7673 + AUAUGAAUCCCAUGGAGAGGUGGC 24 9351 BCL11A-7674 + ACUCGGGUGAUGGGUGGC 18 9352 BCL11A-7675 + CACUCGGGUGAUGGGUGGC 19 9353 BCL11A-7676 + GCACUCGGGUGAUGGGUGGC 20 9354 BCL11A-7677 + GGCACUCGGGUGAUGGGUGGC 21 9355 BCL11A-7678 + AGGCACUCGGGUGAUGGGUGGC 22 9356 BCL11A-7679 + AAGGCACUCGGGUGAUGGGUGGC 23 9357 BCL11A-7680 + AAAGGCACUCGGGUGAUGGGUGGC 24 9358 BCL11A-7681 + CUUUUGAGCUGGGCCUGC 18 9359 BCL11A-7682 + UCUUUUGAGCUGGGCCUGC 19 9360 BCL11A-7683 + CUCUUUUGAGCUGGGCCUGC 20 9361 BCL11A-7684 + CCUCUUUUGAGCUGGGCCUGC 21 9362 BCL11A-7685 + CCCUCUUUUGAGCUGGGCCUGC 22 9363 BCL11A-7686 + GCCCUCUUUUGAGCUGGGCCUGC 23 9364 BCL11A-7687 + UGCCCUCUUUUGAGCUGGGCCUGC 24 9365 BCL11A-7688 + AAGGGAUCUUUGAGCUGC 18 9366 BCL11A-7689 + GAAGGGAUCUUUGAGCUGC 19 9367 BCL11A-7690 + GGAAGGGAUCUUUGAGCUGC 20 9368 BCL11A-7691 + AGGAAGGGAUCUUUGAGCUGC 21 9369 BCL11A-7692 + AAGGAAGGGAUCUUUGAGCUGC 22 9370 BCL11A-7693 + UAAGGAAGGGAUCUUUGAGCUGC 23 9371 BCL11A-7694 + CUAAGGAAGGGAUCUUUGAGCUGC 24 9372 BCL11A-7695 + GCCUCGCUGAAGUGCUGC 18 9373 BCL11A-7696 + GGCCUCGCUGAAGUGCUGC 19 9374 BCL11A-7697 + AGGCCUCGCUGAAGUGCUGC 20 9375 BCL11A-7698 + AAGGCCUCGCUGAAGUGCUGC 21 9376 BCL11A-7699 + GAAGGCCUCGCUGAAGUGCUGC 22 9377 BCL11A-7700 + GGAAGGCCUCGCUGAAGUGCUGC 23 9378 BCL11A-7701 + UGGAAGGCCUCGCUGAAGUGCUGC 24 9379 BCL11A-7702 + GUGUUCUGUGCGUGUUGC 18 9380 BCL11A-7703 + AGUGUUCUGUGCGUGUUGC 19 9381 BCL11A-7704 + GAGUGUUCUGUGCGUGUUGC 20 9382 BCL11A-7705 + UGAGUGUUCUGUGCGUGUUGC 21 9383 BCL11A-7706 + AUGAGUGUUCUGUGCGUGUUGC 22 9384 BCL11A-7707 + CAUGAGUGUUCUGUGCGUGUUGC 23 9385 BCL11A-7708 + CCAUGAGUGUUCUGUGCGUGUUGC 24 9386 BCL11A-7709 + CGAAAACUGCCACACAUC 18 9387 BCL11A-7710 + CCGAAAACUGCCACACAUC 19 9388 BCL11A-7711 + UCCGAAAACUGCCACACAUC 20 9389 BCL11A-7712 + AUCCGAAAACUGCCACACAUC 21 9390 BCL11A-7713 + CAUCCGAAAACUGCCACACAUC 22 9391 BCL11A-7714 + CCAUCCGAAAACUGCCACACAUC 23 9392 BCL11A-7715 + UCCAUCCGAAAACUGCCACACAUC 24 9393 BCL11A-7716 + UUGGGGUCGUUCUCGCUC 18 9394 BCL11A-7717 + GUUGGGGUCGUUCUCGCUC 19 9395 BCL11A-7718 + GGUUGGGGUCGUUCUCGCUC 20 9396 BCL11A-7719 + AGGUUGGGGUCGUUCUCGCUC 21 9397 BCL11A-7720 + CAGGUUGGGGUCGUUCUCGCUC 22 9398 BCL11A-7721 + UCAGGUUGGGGUCGUUCUCGCUC 23 9399 BCL11A-7722 + AUCAGGUUGGGGUCGUUCUCGCUC 24 9400 BCL11A-7723 + CUCAGAACUUAAGGGCUC 18 9401 BCL11A-7724 + UCUCAGAACUUAAGGGCUC 19 9402 BCL11A-7725 + UUCUCAGAACUUAAGGGCUC 20 9403 BCL11A-7726 + UUUCUCAGAACUUAAGGGCUC 21 9404 BCL11A-7727 + UUUUCUCAGAACUUAAGGGCUC 22 9405 BCL11A-7728 + AUUUUCUCAGAACUUAAGGGCUC 23 9406 BCL11A-7729 + AAUUUUCUCAGAACUUAAGGGCUC 24 9407 BCL11A-7730 + GACAUUCUGCACCUAGUC 18 9408 BCL11A-7731 + GGACAUUCUGCACCUAGUC 19 9409 BCL11A-7732 + AGGACAUUCUGCACCUAGUC 20 9410 BCL11A-7733 + AAGGACAUUCUGCACCUAGUC 21 9411 BCL11A-7734 + GAAGGACAUUCUGCACCUAGUC 22 9412 BCL11A-7735 + GGAAGGACAUUCUGCACCUAGUC 23 9413 BCL11A-7736 + GGGAAGGACAUUCUGCACCUAGUC 24 9414 BCL11A-7737 + UCGUCGGACUUGACCGUC 18 9415 BCL11A-7738 + GUCGUCGGACUUGACCGUC 19 9416 BCL11A-7739 + CGUCGUCGGACUUGACCGUC 20 9417 BCL11A-7740 + CCGUCGUCGGACUUGACCGUC 21 9418 BCL11A-7741 + ACCGUCGUCGGACUUGACCGUC 22 9419 BCL11A-7742 + GACCGUCGUCGGACUUGACCGUC 23 9420 BCL11A-7743 + AGACCGUCGUCGGACUUGACCGUC 24 9421 BCL11A-7744 + AUACCAACCCGCGGGGUC 18 9422 BCL11A-7745 + GAUACCAACCCGCGGGGUC 19 9423 BCL11A-6052 + GGAUACCAACCCGCGGGGUC 20 9424 BCL11A-7746 + GGGAUACCAACCCGCGGGGUC 21 9425 BCL11A-7747 + AGGGAUACCAACCCGCGGGGUC 22 9426 BCL11A-7748 + AAGGGAUACCAACCCGCGGGGUC 23 9427 BCL11A-7749 + GAAGGGAUACCAACCCGCGGGGUC 24 9428 BCL11A-7750 + GGCAGGUCGAACUCCUUC 18 9429 BCL11A-7751 + GGGCAGGUCGAACUCCUUC 19 9430 BCL11A-7752 + GGGGCAGGUCGAACUCCUUC 20 9431 BCL11A-7753 + GGGGGCAGGUCGAACUCCUUC 21 9432 BCL11A-7754 + CGGGGGCAGGUCGAACUCCUUC 22 9433 BCL11A-7755 + CCGGGGGCAGGUCGAACUCCUUC 23 9434 BCL11A-7756 + GCCGGGGGCAGGUCGAACUCCUUC 24 9435 BCL11A-7757 + GUCGCUGGUGCCGGGUUC 18 9436 BCL11A-7758 + AGUCGCUGGUGCCGGGUUC 19 9437 BCL11A-6058 + AAGUCGCUGGUGCCGGGUUC 20 9438 BCL11A-7759 + CAAGUCGCUGGUGCCGGGUUC 21 9439 BCL11A-7760 + CCAAGUCGCUGGUGCCGGGUUC 22 9440 BCL11A-7761 + ACCAAGUCGCUGGUGCCGGGUUC 23 9441 BCL11A-7762 + CACCAAGUCGCUGGUGCCGGGUUC 24 9442 BCL11A-7763 + CGGUGGUGGACUAAACAG 18 9443 BCL11A-7764 + UCGGUGGUGGACUAAACAG 19 9444 BCL11A-6063 + CUCGGUGGUGGACUAAACAG 20 9445 BCL11A-7765 + UCUCGGUGGUGGACUAAACAG 21 9446 BCL11A-7766 + GUCUCGGUGGUGGACUAAACAG 22 9447 BCL11A-7767 + UGUCUCGGUGGUGGACUAAACAG 23 9448 BCL11A-7768 + AUGUCUCGGUGGUGGACUAAACAG 24 9449 BCL11A-7769 + GAAAGAGGUUGGAGACAG 18 9450 BCL11A-7770 + AGAAAGAGGUUGGAGACAG 19 9451 BCL11A-6064 + UAGAAAGAGGUUGGAGACAG 20 9452 BCL11A-7771 + CUAGAAAGAGGUUGGAGACAG 21 9453 BCL11A-7772 + CCUAGAAAGAGGUUGGAGACAG 22 9454 BCL11A-7773 + ACCUAGAAAGAGGUUGGAGACAG 23 9455 BCL11A-7774 + AACCUAGAAAGAGGUUGGAGACAG 24 9456 BCL11A-7775 + AGGAGGGGCGGAUUGCAG 18 9457 BCL11A-7776 + GAGGAGGGGCGGAUUGCAG 19 9458 BCL11A-6069 + GGAGGAGGGGCGGAUUGCAG 20 9459 BCL11A-7777 + GGGAGGAGGGGCGGAUUGCAG 21 9460 BCL11A-7778 + AGGGAGGAGGGGCGGAUUGCAG 22 9461 BCL11A-7779 + GAGGGAGGAGGGGCGGAUUGCAG 23 9462 BCL11A-7780 + GGAGGGAGGAGGGGCGGAUUGCAG 24 9463 BCL11A-7781 + AAGAGGUUGGAGACAGAG 18 9464 BCL11A-7782 + AAAGAGGUUGGAGACAGAG 19 9465 BCL11A-7783 + GAAAGAGGUUGGAGACAGAG 20 9466 BCL11A-7784 + AGAAAGAGGUUGGAGACAGAG 21 9467 BCL11A-7785 + UAGAAAGAGGUUGGAGACAGAG 22 9468 BCL11A-7786 + CUAGAAAGAGGUUGGAGACAGAG 23 9469 BCL11A-7787 + CCUAGAAAGAGGUUGGAGACAGAG 24 9470 BCL11A-7788 + GAGGGGCGGAUUGCAGAG 18 9471 BCL11A-7789 + GGAGGGGCGGAUUGCAGAG 19 9472 BCL11A-7790 + AGGAGGGGCGGAUUGCAGAG 20 9473 BCL11A-7791 + GAGGAGGGGCGGAUUGCAGAG 21 9474 BCL11A-7792 + GGAGGAGGGGCGGAUUGCAGAG 22 9475 BCL11A-7793 + GGGAGGAGGGGCGGAUUGCAGAG 23 9476 BCL11A-7794 + AGGGAGGAGGGGCGGAUUGCAGAG 24 9477 BCL11A-7795 + AGCUUGAUGCGCUUAGAG 18 9478 BCL11A-7796 + GAGCUUGAUGCGCUUAGAG 19 9479 BCL11A-7797 + CGAGCUUGAUGCGCUUAGAG 20 9480 BCL11A-7798 + UCGAGCUUGAUGCGCUUAGAG 21 9481 BCL11A-7799 + CUCGAGCUUGAUGCGCUUAGAG 22 9482 BCL11A-7800 + UCUCGAGCUUGAUGCGCUUAGAG 23 9483 BCL11A-7801 + UUCUCGAGCUUGAUGCGCUUAGAG 24 9484 BCL11A-7802 + GAGAAGGGGCUCAGCGAG 18 9485 BCL11A-7803 + AGAGAAGGGGCUCAGCGAG 19 9486 BCL11A-7804 + UAGAGAAGGGGCUCAGCGAG 20 9487 BCL11A-7805 + UUAGAGAAGGGGCUCAGCGAG 21 9488 BCL11A-7806 + CUUAGAGAAGGGGCUCAGCGAG 22 9489 BCL11A-7807 + GCUUAGAGAAGGGGCUCAGCGAG 23 9490 BCL11A-7808 + CGCUUAGAGAAGGGGCUCAGCGAG 24 9491 BCL11A-7809 + GGAUUGCAGAGGAGGGAG 18 9492 BCL11A-7810 + CGGAUUGCAGAGGAGGGAG 19 9493 BCL11A-6075 + GCGGAUUGCAGAGGAGGGAG 20 9494 BCL11A-7811 + GGCGGAUUGCAGAGGAGGGAG 21 9495 BCL11A-7812 + GGGCGGAUUGCAGAGGAGGGAG 22 9496 BCL11A-7813 + GGGGCGGAUUGCAGAGGAGGGAG 23 9497 BCL11A-7814 + AGGGGCGGAUUGCAGAGGAGGGAG 24 9498 BCL11A-7815 + CCGGGGGCUGGGAGGGAG 18 9499 BCL11A-7816 + ACCGGGGGCUGGGAGGGAG 19 9500 BCL11A-7817 + GACCGGGGGCUGGGAGGGAG 20 9501 BCL11A-7818 + UGACCGGGGGCUGGGAGGGAG 21 9502 BCL11A-7819 + UUGACCGGGGGCUGGGAGGGAG 22 9503 BCL11A-7820 + CUUGACCGGGGGCUGGGAGGGAG 23 9504 BCL11A-7821 + ACUUGACCGGGGGCUGGGAGGGAG 24 9505 BCL11A-7822 + CUGAAGUGCUGCAUGGAG 18 9506 BCL11A-7823 + GCUGAAGUGCUGCAUGGAG 19 9507 BCL11A-7824 + CGCUGAAGUGCUGCAUGGAG 20 9508 BCL11A-7825 + UCGCUGAAGUGCUGCAUGGAG 21 9509 BCL11A-7826 + CUCGCUGAAGUGCUGCAUGGAG 22 9510 BCL11A-7827 + CCUCGCUGAAGUGCUGCAUGGAG 23 9511 BCL11A-7828 + GCCUCGCUGAAGUGCUGCAUGGAG 24 9512 BCL11A-7829 + CGUCUGCCCUCUUUUGAG 18 9513 BCL11A-7830 + GCGUCUGCCCUCUUUUGAG 19 9514 BCL11A-7831 + UGCGUCUGCCCUCUUUUGAG 20 9515 BCL11A-7832 + CUGCGUCUGCCCUCUUUUGAG 21 9516 BCL11A-7833 + GCUGCGUCUGCCCUCUUUUGAG 22 9517 BCL11A-7834 + CGCUGCGUCUGCCCUCUUUUGAG 23 9518 BCL11A-7835 + UCGCUGCGUCUGCCCUCUUUUGAG 24 9519 BCL11A-7836 + CCGAGGAGUGCUCCGACG 18 9520 BCL11A-7837 + UCCGAGGAGUGCUCCGACG 19 9521 BCL11A-6080 + CUCCGAGGAGUGCUCCGACG 20 9522 BCL11A-7838 + UCUCCGAGGAGUGCUCCGACG 21 9523 BCL11A-7839 + UUCUCCGAGGAGUGCUCCGACG 22 9524 BCL11A-7840 + GUUCUCCGAGGAGUGCUCCGACG 23 9525 BCL11A-7841 + CGUUCUCCGAGGAGUGCUCCGACG 24 9526 BCL11A-7842 + ACCAUGCCCUGCAUGACG 18 9527 BCL11A-7843 + CACCAUGCCCUGCAUGACG 19 9528 BCL11A-7844 + GCACCAUGCCCUGCAUGACG 20 9529 BCL11A-7845 + AGCACCAUGCCCUGCAUGACG 21 9530 BCL11A-7846 + GAGCACCAUGCCCUGCAUGACG 22 9531 BCL11A-7847 + UGAGCACCAUGCCCUGCAUGACG 23 9532 BCL11A-7848 + CUGAGCACCAUGCCCUGCAUGACG 24 9533 BCL11A-7849 + CCGAGGCCGACUCGCCCG 18 9534 BCL11A-7850 + CCCGAGGCCGACUCGCCCG 19 9535 BCL11A-6088 + CCCCGAGGCCGACUCGCCCG 20 9536 BCL11A-7851 + CCCCCGAGGCCGACUCGCCCG 21 9537 BCL11A-7852 + CCCCCCGAGGCCGACUCGCCCG 22 9538 BCL11A-7853 + GCCCCCCGAGGCCGACUCGCCCG 23 9539 BCL11A-7854 + GGCCCCCCGAGGCCGACUCGCCCG 24 9540 BCL11A-7855 + CUGGAGGCCGCGUAGCCG 18 9541 BCL11A-7856 + CCUGGAGGCCGCGUAGCCG 19 9542 BCL11A-7857 + GCCUGGAGGCCGCGUAGCCG 20 9543 BCL11A-7858 + UGCCUGGAGGCCGCGUAGCCG 21 9544 BCL11A-7859 + CUGCCUGGAGGCCGCGUAGCCG 22 9545 BCL11A-7860 + GCUGCCUGGAGGCCGCGUAGCCG 23 9546 BCL11A-7861 + AGCUGCCUGGAGGCCGCGUAGCCG 24 9547 BCL11A-7862 + AAUUUGAACGUCUUGCCG 18 9548 BCL11A-7863 + AAAUUUGAACGUCUUGCCG 19 9549 BCL11A-7864 + GAAAUUUGAACGUCUUGCCG 20 9550 BCL11A-7865 + UGAAAUUUGAACGUCUUGCCG 21 9551 BCL11A-7866 + CUGAAAUUUGAACGUCUUGCCG 22 9552 BCL11A-7867 + UCUGAAAUUUGAACGUCUUGCCG 23 9553 BCL11A-7868 + CUCUGAAAUUUGAACGUCUUGCCG 24 9554 BCL11A-7869 + UCUCCGAGGAGUGCUCCG 18 9555 BCL11A-7870 + UUCUCCGAGGAGUGCUCCG 19 9556 BCL11A-7871 + GUUCUCCGAGGAGUGCUCCG 20 9557 BCL11A-7872 + CGUUCUCCGAGGAGUGCUCCG 21 9558 BCL11A-7873 + CCGUUCUCCGAGGAGUGCUCCG 22 9559 BCL11A-7874 + CCCGUUCUCCGAGGAGUGCUCCG 23 9560 BCL11A-7875 + UCCCGUUCUCCGAGGAGUGCUCCG 24 9561 BCL11A-7876 + CGCUGGUGCCGGGUUCCG 18 9562 BCL11A-7877 + UCGCUGGUGCCGGGUUCCG 19 9563 BCL11A-6096 + GUCGCUGGUGCCGGGUUCCG 20 9564 BCL11A-7878 + AGUCGCUGGUGCCGGGUUCCG 21 9565 BCL11A-7879 + AAGUCGCUGGUGCCGGGUUCCG 22 9566 BCL11A-7880 + CAAGUCGCUGGUGCCGGGUUCCG 23 9567 BCL11A-7881 + CCAAGUCGCUGGUGCCGGGUUCCG 24 9568 BCL11A-7882 + GCCGGCCUGGGGACAGCG 18 9569 BCL11A-7883 + GGCCGGCCUGGGGACAGCG 19 9570 BCL11A-7884 + GGGCCGGCCUGGGGACAGCG 20 9571 BCL11A-7885 + UGGGCCGGCCUGGGGACAGCG 21 9572 BCL11A-7886 + CUGGGCCGGCCUGGGGACAGCG 22 9573 BCL11A-7887 + GCUGGGCCGGCCUGGGGACAGCG 23 9574 BCL11A-7888 + GGCUGGGCCGGCCUGGGGACAGCG 24 9575 BCL11A-7889 + GGUUCCGGGGAGCUGGCG 18 9576 BCL11A-7890 + GGGUUCCGGGGAGCUGGCG 19 9577 BCL11A-7891 + CGGGUUCCGGGGAGCUGGCG 20 9578 BCL11A-7892 + CCGGGUUCCGGGGAGCUGGCG 21 9579 BCL11A-7893 + GCCGGGUUCCGGGGAGCUGGCG 22 9580 BCL11A-7894 + UGCCGGGUUCCGGGGAGCUGGCG 23 9581 BCL11A-7895 + GUGCCGGGUUCCGGGGAGCUGGCG 24 9582 BCL11A-7896 + CCCCAGGCGCUCUAUGCG 18 9583 BCL11A-7897 + CCCCCAGGCGCUCUAUGCG 19 9584 BCL11A-7898 + GCCCCCAGGCGCUCUAUGCG 20 9585 BCL11A-7899 + CGCCCCCAGGCGCUCUAUGCG 21 9586 BCL11A-7900 + CCGCCCCCAGGCGCUCUAUGCG 22 9587 BCL11A-7901 + UCCGCCCCCAGGCGCUCUAUGCG 23 9588 BCL11A-7902 + UUCCGCCCCCAGGCGCUCUAUGCG 24 9589 BCL11A-7903 + ACCUGGUGGAAGGCCUCG 18 9590 BCL11A-7904 + GACCUGGUGGAAGGCCUCG 19 9591 BCL11A-7905 + GGACCUGGUGGAAGGCCUCG 20 9592 BCL11A-7906 + AGGACCUGGUGGAAGGCCUCG 21 9593 BCL11A-7907 + CAGGACCUGGUGGAAGGCCUCG 22 9594 BCL11A-7908 + CCAGGACCUGGUGGAAGGCCUCG 23 9595 BCL11A-7909 + CCCAGGACCUGGUGGAAGGCCUCG 24 9596 BCL11A-7910 + GCGGUGGAGAGACCGUCG 18 9597 BCL11A-7911 + GGCGGUGGAGAGACCGUCG 19 9598 BCL11A-7912 + UGGCGGUGGAGAGACCGUCG 20 9599 BCL11A-7913 + CUGGCGGUGGAGAGACCGUCG 21 9600 BCL11A-7914 + GCUGGCGGUGGAGAGACCGUCG 22 9601 BCL11A-7915 + AGCUGGCGGUGGAGAGACCGUCG 23 9602 BCL11A-7916 + GAGCUGGCGGUGGAGAGACCGUCG 24 9603 BCL11A-7917 + GAGUCUCCGAAGCUAAGG 18 9604 BCL11A-7918 + GGAGUCUCCGAAGCUAAGG 19 9605 BCL11A-7919 + UGGAGUCUCCGAAGCUAAGG 20 9606 BCL11A-7920 + CUGGAGUCUCCGAAGCUAAGG 21 9607 BCL11A-7921 + UCUGGAGUCUCCGAAGCUAAGG 22 9608 BCL11A-7922 + GUCUGGAGUCUCCGAAGCUAAGG 23 9609 BCL11A-7923 + UGUCUGGAGUCUCCGAAGCUAAGG 24 9610 BCL11A-7924 + GGUGGUGGACUAAACAGG 18 9611 BCL11A-7925 + CGGUGGUGGACUAAACAGG 19 9612 BCL11A-6111 + UCGGUGGUGGACUAAACAGG 20 9613 BCL11A-7926 + CUCGGUGGUGGACUAAACAGG 21 9614 BCL11A-7927 + UCUCGGUGGUGGACUAAACAGG 22 9615 BCL11A-7928 + GUCUCGGUGGUGGACUAAACAGG 23 9616 BCL11A-7929 + UGUCUCGGUGGUGGACUAAACAGG 24 9617 BCL11A-7930 + AGGGGGGGCGUCGCCAGG 18 9618 BCL11A-7931 + GAGGGGGGGCGUCGCCAGG 19 9619 BCL11A-7932 + GGAGGGGGGGCGUCGCCAGG 20 9620 BCL11A-7933 + GGGAGGGGGGGCGUCGCCAGG 21 9621 BCL11A-7934 + AGGGAGGGGGGGCGUCGCCAGG 22 9622 BCL11A-7935 + GAGGGAGGGGGGGCGUCGCCAGG 23 9623 BCL11A-7936 + GGAGGGAGGGGGGGCGUCGCCAGG 24 9624 BCL11A-7937 + AAGCGCCCUUCUGCCAGG 18 9625 BCL11A-7938 + AAAGCGCCCUUCUGCCAGG 19 9626 BCL11A-7939 + GAAAGCGCCCUUCUGCCAGG 20 9627 BCL11A-7940 + GGAAAGCGCCCUUCUGCCAGG 21 9628 BCL11A-7941 + UGGAAAGCGCCCUUCUGCCAGG 22 9629 BCL11A-7942 + GUGGAAAGCGCCCUUCUGCCAGG 23 9630 BCL11A-7943 + GGUGGAAAGCGCCCUUCUGCCAGG 24 9631 BCL11A-7944 + AUCGCGGCCGGGGGCAGG 18 9632 BCL11A-7945 + CAUCGCGGCCGGGGGCAGG 19 9633 BCL11A-7946 + GCAUCGCGGCCGGGGGCAGG 20 9634 BCL11A-7947 + GGCAUCGCGGCCGGGGGCAGG 21 9635 BCL11A-7948 + GGGCAUCGCGGCCGGGGGCAGG 22 9636 BCL11A-7949 + UGGGCAUCGCGGCCGGGGGCAGG 23 9637 BCL11A-7950 + UUGGGCAUCGCGGCCGGGGGCAGG 24 9638 BCL11A-7951 + CCGUUCUCCGGGAUCAGG 18 9639 BCL11A-7952 + CCCGUUCUCCGGGAUCAGG 19 9640 BCL11A-7953 + CCCCGUUCUCCGGGAUCAGG 20 9641 BCL11A-7954 + UCCCCGUUCUCCGGGAUCAGG 21 9642 BCL11A-7955 + GUCCCCGUUCUCCGGGAUCAGG 22 9643 BCL11A-7956 + CGUCCCCGUUCUCCGGGAUCAGG 23 9644 BCL11A-7957 + UCGUCCCCGUUCUCCGGGAUCAGG 24 9645 BCL11A-7958 + GAAGAACCUAGAAAGAGG 18 9646 BCL11A-7959 + UGAAGAACCUAGAAAGAGG 19 9647 BCL11A-7960 + GUGAAGAACCUAGAAAGAGG 20 9648 BCL11A-7961 + UGUGAAGAACCUAGAAAGAGG 21 9649 BCL11A-7962 + GUGUGAAGAACCUAGAAAGAGG 22 9650 BCL11A-7963 + UGUGUGAAGAACCUAGAAAGAGG 23 9651 BCL11A-7964 + GUGUGUGAAGAACCUAGAAAGAGG 24 9652 BCL11A-7965 + AGAGGUUGGAGACAGAGG 18 9653 BCL11A-7966 + AAGAGGUUGGAGACAGAGG 19 9654 BCL11A-6113 + AAAGAGGUUGGAGACAGAGG 20 9655 BCL11A-7967 + GAAAGAGGUUGGAGACAGAGG 21 9656 BCL11A-7968 + AGAAAGAGGUUGGAGACAGAGG 22 9657 BCL11A-7969 + UAGAAAGAGGUUGGAGACAGAGG 23 9658 BCL11A-7970 + CUAGAAAGAGGUUGGAGACAGAGG 24 9659 BCL11A-7971 + AGGGGCGGAUUGCAGAGG 18 9660 BCL11A-7972 + GAGGGGCGGAUUGCAGAGG 19 9661 BCL11A-6114 + GGAGGGGCGGAUUGCAGAGG 20 9662 BCL11A-7973 + AGGAGGGGCGGAUUGCAGAGG 21 9663 BCL11A-7974 + GAGGAGGGGCGGAUUGCAGAGG 22 9664 BCL11A-7975 + GGAGGAGGGGCGGAUUGCAGAGG 23 9665 BCL11A-7976 + GGGAGGAGGGGCGGAUUGCAGAGG 24 9666 BCL11A-7977 + GGCGGAUUGCAGAGGAGG 18 9667 BCL11A-7978 + GGGCGGAUUGCAGAGGAGG 19 9668 BCL11A-7979 + GGGGCGGAUUGCAGAGGAGG 20 9669 BCL11A-7980 + AGGGGCGGAUUGCAGAGGAGG 21 9670 BCL11A-7981 + GAGGGGCGGAUUGCAGAGGAGG 22 9671 BCL11A-7982 + GGAGGGGCGGAUUGCAGAGGAGG 23 9672 BCL11A-7983 + AGGAGGGGCGGAUUGCAGAGGAGG 24 9673 BCL11A-7984 + GAUUGCAGAGGAGGGAGG 18 9674 BCL11A-7985 + GGAUUGCAGAGGAGGGAGG 19 9675 BCL11A-6118 + CGGAUUGCAGAGGAGGGAGG 20 9676 BCL11A-7986 + GCGGAUUGCAGAGGAGGGAGG 21 9677 BCL11A-7987 + GGCGGAUUGCAGAGGAGGGAGG 22 9678 BCL11A-7988 + GGGCGGAUUGCAGAGGAGGGAGG 23 9679 BCL11A-7989 + GGGGCGGAUUGCAGAGGAGGGAGG 24 9680 BCL11A-7990 + CGGGGGCUGGGAGGGAGG 18 9681 BCL11A-7991 + CCGGGGGCUGGGAGGGAGG 19 9682 BCL11A-6119 + ACCGGGGGCUGGGAGGGAGG 20 9683 BCL11A-7992 + GACCGGGGGCUGGGAGGGAGG 21 9684 BCL11A-7993 + UGACCGGGGGCUGGGAGGGAGG 22 9685 BCL11A-7994 + UUGACCGGGGGCUGGGAGGGAGG 23 9686 BCL11A-7995 + CUUGACCGGGGGCUGGGAGGGAGG 24 9687 BCL11A-7996 + UGACCGGGGGCUGGGAGG 18 9688 BCL11A-7997 + UUGACCGGGGGCUGGGAGG 19 9689 BCL11A-7998 + CUUGACCGGGGGCUGGGAGG 20 9690 BCL11A-7999 + ACUUGACCGGGGGCUGGGAGG 21 9691 BCL11A-8000 + GACUUGACCGGGGGCUGGGAGG 22 9692 BCL11A-8001 + GGACUUGACCGGGGGCUGGGAGG 23 9693 BCL11A-8002 + UGGACUUGACCGGGGGCUGGGAGG 24 9694 BCL11A-8003 + CCGUGUUGGGCAUCGCGG 18 9695 BCL11A-8004 + UCCGUGUUGGGCAUCGCGG 19 9696 BCL11A-8005 + CUCCGUGUUGGGCAUCGCGG 20 9697 BCL11A-8006 + UCUCCGUGUUGGGCAUCGCGG 21 9698 BCL11A-8007 + UUCUCCGUGUUGGGCAUCGCGG 22 9699 BCL11A-8008 + GUUCUCCGUGUUGGGCAUCGCGG 23 9700 BCL11A-8009 + CGUUCUCCGUGUUGGGCAUCGCGG 24 9701 BCL11A-8010 + GUUCCGGGGAGCUGGCGG 18 9702 BCL11A-8011 + GGUUCCGGGGAGCUGGCGG 19 9703 BCL11A-6125 + GGGUUCCGGGGAGCUGGCGG 20 9704 BCL11A-8012 + CGGGUUCCGGGGAGCUGGCGG 21 9705 BCL11A-8013 + CCGGGUUCCGGGGAGCUGGCGG 22 9706 BCL11A-8014 + GCCGGGUUCCGGGGAGCUGGCGG 23 9707 BCL11A-8015 + UGCCGGGUUCCGGGGAGCUGGCGG 24 9708 BCL11A-8016 + CCCAGGCGCUCUAUGCGG 18 9709 BCL11A-8017 + CCCCAGGCGCUCUAUGCGG 19 9710 BCL11A-6126 + CCCCCAGGCGCUCUAUGCGG 20 9711 BCL11A-8018 + GCCCCCAGGCGCUCUAUGCGG 21 9712 BCL11A-8019 + CGCCCCCAGGCGCUCUAUGCGG 22 9713 BCL11A-8020 + CCGCCCCCAGGCGCUCUAUGCGG 23 9714 BCL11A-8021 + UCCGCCCCCAGGCGCUCUAUGCGG 24 9715 BCL11A-8022 + GUGGUGGACUAAACAGGG 18 9716 BCL11A-8023 + GGUGGUGGACUAAACAGGG 19 9717 BCL11A-6131 + CGGUGGUGGACUAAACAGGG 20 9718 BCL11A-8024 + UCGGUGGUGGACUAAACAGGG 21 9719 BCL11A-8025 + CUCGGUGGUGGACUAAACAGGG 22 9720 BCL11A-8026 + UCUCGGUGGUGGACUAAACAGGG 23 9721 BCL11A-8027 + GUCUCGGUGGUGGACUAAACAGGG 24 9722 BCL11A-8028 + GCGGAUUGCAGAGGAGGG 18 9723 BCL11A-8029 + GGCGGAUUGCAGAGGAGGG 19 9724 BCL11A-6133 + GGGCGGAUUGCAGAGGAGGG 20 9725 BCL11A-8030 + GGGGCGGAUUGCAGAGGAGGG 21 9726 BCL11A-8031 + AGGGGCGGAUUGCAGAGGAGGG 22 9727 BCL11A-8032 + GAGGGGCGGAUUGCAGAGGAGGG 23 9728 BCL11A-8033 + GGAGGGGCGGAUUGCAGAGGAGGG 24 9729 BCL11A-8034 + GACCGGGGGCUGGGAGGG 18 9730 BCL11A-8035 + UGACCGGGGGCUGGGAGGG 19 9731 BCL11A-6135 + UUGACCGGGGGCUGGGAGGG 20 9732 BCL11A-8036 + CUUGACCGGGGGCUGGGAGGG 21 9733 BCL11A-8037 + ACUUGACCGGGGGCUGGGAGGG 22 9734 BCL11A-8038 + GACUUGACCGGGGGCUGGGAGGG 23 9735 BCL11A-8039 + GGACUUGACCGGGGGCUGGGAGGG 24 9736 BCL11A-8040 + AGUAACCUUUGCAUAGGG 18 9737 BCL11A-8041 + CAGUAACCUUUGCAUAGGG 19 9738 BCL11A-8042 + GCAGUAACCUUUGCAUAGGG 20 9739 BCL11A-8043 + UGCAGUAACCUUUGCAUAGGG 21 9740 BCL11A-8044 + UUGCAGUAACCUUUGCAUAGGG 22 9741 BCL11A-8045 + GUUGCAGUAACCUUUGCAUAGGG 23 9742 BCL11A-8046 + GGUUGCAGUAACCUUUGCAUAGGG 24 9743 BCL11A-8047 + GCCCUGCAUGACGUCGGG 18 9744 BCL11A-8048 + UGCCCUGCAUGACGUCGGG 19 9745 BCL11A-8049 + AUGCCCUGCAUGACGUCGGG 20 9746 BCL11A-8050 + CAUGCCCUGCAUGACGUCGGG 21 9747 BCL11A-8051 + CCAUGCCCUGCAUGACGUCGGG 22 9748 BCL11A-8052 + ACCAUGCCCUGCAUGACGUCGGG 23 9749 BCL11A-8053 + CACCAUGCCCUGCAUGACGUCGGG 24 9750 BCL11A-8054 + CUUGGACUUGACCGGGGG 18 9751 BCL11A-8055 + ACUUGGACUUGACCGGGGG 19 9752 BCL11A-8056 + GACUUGGACUUGACCGGGGG 20 9753 BCL11A-8057 + UGACUUGGACUUGACCGGGGG 21 9754 BCL11A-8058 + AUGACUUGGACUUGACCGGGGG 22 9755 BCL11A-8059 + CAUGACUUGGACUUGACCGGGGG 23 9756 BCL11A-8060 + GCAUGACUUGGACUUGACCGGGGG 24 9757 BCL11A-8061 + ACUUGACCGGGGGCUGGG 18 9758 BCL11A-8062 + GACUUGACCGGGGGCUGGG 19 9759 BCL11A-6146 + GGACUUGACCGGGGGCUGGG 20 9760 BCL11A-8063 + UGGACUUGACCGGGGGCUGGG 21 9761 BCL11A-8064 + UUGGACUUGACCGGGGGCUGGG 22 9762 BCL11A-8065 + CUUGGACUUGACCGGGGGCUGGG 23 9763 BCL11A-8066 + ACUUGGACUUGACCGGGGGCUGGG 24 9764 BCL11A-8067 + CAUGGAGAGGUGGCUGGG 18 9765 BCL11A-8068 + CCAUGGAGAGGUGGCUGGG 19 9766 BCL11A-8069 + CCCAUGGAGAGGUGGCUGGG 20 9767 BCL11A-8070 + UCCCAUGGAGAGGUGGCUGGG 21 9768 BCL11A-8071 + AUCCCAUGGAGAGGUGGCUGGG 22 9769 BCL11A-8072 + AAUCCCAUGGAGAGGUGGCUGGG 23 9770 BCL11A-8073 + GAAUCCCAUGGAGAGGUGGCUGGG 24 9771 BCL11A-8074 + AAACAGGGGGGGAGUGGG 18 9772 BCL11A-8075 + UAAACAGGGGGGGAGUGGG 19 9773 BCL11A-6147 + CUAAACAGGGGGGGAGUGGG 20 9774 BCL11A-8076 + ACUAAACAGGGGGGGAGUGGG 21 9775 BCL11A-8077 + GACUAAACAGGGGGGGAGUGGG 22 9776 BCL11A-8078 + GGACUAAACAGGGGGGGAGUGGG 23 9777 BCL11A-8079 + UGGACUAAACAGGGGGGGAGUGGG 24 9778 BCL11A-8080 + UCCUAGAGAAAUCCAUGG 18 9779 BCL11A-8081 + CUCCUAGAGAAAUCCAUGG 19 9780 BCL11A-6149 + UCUCCUAGAGAAAUCCAUGG 20 9781 BCL11A-8082 + GUCUCCUAGAGAAAUCCAUGG 21 9782 BCL11A-8083 + AGUCUCCUAGAGAAAUCCAUGG 22 9783 BCL11A-8084 + AAGUCUCCUAGAGAAAUCCAUGG 23 9784 BCL11A-8085 + UAAGUCUCCUAGAGAAAUCCAUGG 24 9785 BCL11A-8086 + UUCUCGCCCAGGACCUGG 18 9786 BCL11A-8087 + CUUCUCGCCCAGGACCUGG 19 9787 BCL11A-6152 + GCUUCUCGCCCAGGACCUGG 20 9788 BCL11A-8088 + UGCUUCUCGCCCAGGACCUGG 21 9789 BCL11A-8089 + AUGCUUCUCGCCCAGGACCUGG 22 9790 BCL11A-8090 + UAUGCUUCUCGCCCAGGACCUGG 23 9791 BCL11A-8091 + UUAUGCUUCUCGCCCAGGACCUGG 24 9792 BCL11A-8092 + GGGCGGCUUGCUACCUGG 18 9793 BCL11A-8093 + AGGGCGGCUUGCUACCUGG 19 9794 BCL11A-8094 + AAGGGCGGCUUGCUACCUGG 20 9795 BCL11A-8095 + GAAGGGCGGCUUGCUACCUGG 21 9796 BCL11A-8096 + GGAAGGGCGGCUUGCUACCUGG 22 9797 BCL11A-8097 + AGGAAGGGCGGCUUGCUACCUGG 23 9798 BCL11A-8098 + CAGGAAGGGCGGCUUGCUACCUGG 24 9799 BCL11A-8099 + GACUUGACCGGGGGCUGG 18 9800 BCL11A-8100 + GGACUUGACCGGGGGCUGG 19 9801 BCL11A-8101 + UGGACUUGACCGGGGGCUGG 20 9802 BCL11A-8102 + UUGGACUUGACCGGGGGCUGG 21 9803 BCL11A-8103 + CUUGGACUUGACCGGGGGCUGG 22 9804 BCL11A-8104 + ACUUGGACUUGACCGGGGGCUGG 23 9805 BCL11A-8105 + GACUUGGACUUGACCGGGGGCUGG 24 9806 BCL11A-8106 + UAAACAGGGGGGGAGUGG 18 9807 BCL11A-8107 + CUAAACAGGGGGGGAGUGG 19 9808 BCL11A-8108 + ACUAAACAGGGGGGGAGUGG 20 9809 BCL11A-8109 + GACUAAACAGGGGGGGAGUGG 21 9810 BCL11A-8110 + GGACUAAACAGGGGGGGAGUGG 22 9811 BCL11A-8111 + UGGACUAAACAGGGGGGGAGUGG 23 9812 BCL11A-8112 + GUGGACUAAACAGGGGGGGAGUGG 24 9813 BCL11A-8113 + AAUCCCAUGGAGAGGUGG 18 9814 BCL11A-8114 + GAAUCCCAUGGAGAGGUGG 19 9815 BCL11A-8115 + UGAAUCCCAUGGAGAGGUGG 20 9816 BCL11A-8116 + AUGAAUCCCAUGGAGAGGUGG 21 9817 BCL11A-8117 + UAUGAAUCCCAUGGAGAGGUGG 22 9818 BCL11A-8118 + AUAUGAAUCCCAUGGAGAGGUGG 23 9819 BCL11A-8119 + AAUAUGAAUCCCAUGGAGAGGUGG 24 9820 BCL11A-8120 + UGCAAUAUGAAUCCCAUG 18 9821 BCL11A-8121 + CUGCAAUAUGAAUCCCAUG 19 9822 BCL11A-8122 + UCUGCAAUAUGAAUCCCAUG 20 9823 BCL11A-8123 + GUCUGCAAUAUGAAUCCCAUG 21 9824 BCL11A-8124 + UGUCUGCAAUAUGAAUCCCAUG 22 9825 BCL11A-8125 + UUGUCUGCAAUAUGAAUCCCAUG 23 9826 BCL11A-8126 + AUUGUCUGCAAUAUGAAUCCCAUG 24 9827 BCL11A-8127 + CUCCUAGAGAAAUCCAUG 18 9828 BCL11A-8128 + UCUCCUAGAGAAAUCCAUG 19 9829 BCL11A-8129 + GUCUCCUAGAGAAAUCCAUG 20 9830 BCL11A-8130 + AGUCUCCUAGAGAAAUCCAUG 21 9831 BCL11A-8131 + AAGUCUCCUAGAGAAAUCCAUG 22 9832 BCL11A-8132 + UAAGUCUCCUAGAGAAAUCCAUG 23 9833 BCL11A-8133 + CUAAGUCUCCUAGAGAAAUCCAUG 24 9834 BCL11A-8134 + UCGGACUUGACCGUCAUG 18 9835 BCL11A-8135 + GUCGGACUUGACCGUCAUG 19 9836 BCL11A-6164 + CGUCGGACUUGACCGUCAUG 20 9837 BCL11A-8136 + UCGUCGGACUUGACCGUCAUG 21 9838 BCL11A-8137 + GUCGUCGGACUUGACCGUCAUG 22 9839 BCL11A-8138 + CGUCGUCGGACUUGACCGUCAUG 23 9840 BCL11A-8139 + CCGUCGUCGGACUUGACCGUCAUG 24 9841 BCL11A-8140 + CUUCUCGCCCAGGACCUG 18 9842 BCL11A-8141 + GCUUCUCGCCCAGGACCUG 19 9843 BCL11A-8142 + UGCUUCUCGCCCAGGACCUG 20 9844 BCL11A-8143 + AUGCUUCUCGCCCAGGACCUG 21 9845 BCL11A-8144 + UAUGCUUCUCGCCCAGGACCUG 22 9846 BCL11A-8145 + UUAUGCUUCUCGCCCAGGACCUG 23 9847 BCL11A-8146 + CUUAUGCUUCUCGCCCAGGACCUG 24 9848 BCL11A-8147 + AUUCUGCACCUAGUCCUG 18 9849 BCL11A-8148 + CAUUCUGCACCUAGUCCUG 19 9850 BCL11A-8149 + ACAUUCUGCACCUAGUCCUG 20 9851 BCL11A-8150 + GACAUUCUGCACCUAGUCCUG 21 9852 BCL11A-8151 + GGACAUUCUGCACCUAGUCCUG 22 9853 BCL11A-8152 + AGGACAUUCUGCACCUAGUCCUG 23 9854 BCL11A-8153 + AAGGACAUUCUGCACCUAGUCCUG 24 9855 BCL11A-6537 + GUUGUACAUGUGUAGCUG 18 9856 BCL11A-6538 + AGUUGUACAUGUGUAGCUG 19 9857 BCL11A-6539 + AAGUUGUACAUGUGUAGCUG 20 9858 BCL11A-6540 + CAAGUUGUACAUGUGUAGCUG 21 9859 BCL11A-6541 + GCAAGUUGUACAUGUGUAGCUG 22 9860 BCL11A-6542 + UGCAAGUUGUACAUGUGUAGCUG 23 9861 BCL11A-6543 + UUGCAAGUUGUACAUGUGUAGCUG 24 9862 BCL11A-8154 + GAGUACACGUUCUCCGUG 18 9863 BCL11A-8155 + CGAGUACACGUUCUCCGUG 19 9864 BCL11A-8156 + GCGAGUACACGUUCUCCGUG 20 9865 BCL11A-8157 + UGCGAGUACACGUUCUCCGUG 21 9866 BCL11A-8158 + CUGCGAGUACACGUUCUCCGUG 22 9867 BCL11A-8159 + ACUGCGAGUACACGUUCUCCGUG 23 9868 BCL11A-8160 + CACUGCGAGUACACGUUCUCCGUG 24 9869 BCL11A-8161 + CCAGCUCCCCGGGCGGUG 18 9870 BCL11A-8162 + UCCAGCUCCCCGGGCGGUG 19 9871 BCL11A-6177 + GUCCAGCUCCCCGGGCGGUG 20 9872 BCL11A-8163 + CGUCCAGCUCCCCGGGCGGUG 21 9873 BCL11A-8164 + CCGUCCAGCUCCCCGGGCGGUG 22 9874 BCL11A-8165 + UCCGUCCAGCUCCCCGGGCGGUG 23 9875 BCL11A-8166 + CUCCGUCCAGCUCCCCGGGCGGUG 24 9876 BCL11A-8167 + UCCGGGGAGCUGGCGGUG 18 9877 BCL11A-8168 + UUCCGGGGAGCUGGCGGUG 19 9878 BCL11A-8169 + GUUCCGGGGAGCUGGCGGUG 20 9879 BCL11A-8170 + GGUUCCGGGGAGCUGGCGGUG 21 9880 BCL11A-8171 + GGGUUCCGGGGAGCUGGCGGUG 22 9881 BCL11A-8172 + CGGGUUCCGGGGAGCUGGCGGUG 23 9882 BCL11A-8173 + CCGGGUUCCGGGGAGCUGGCGGUG 24 9883 BCL11A-8174 + CCAAGUGAUGUCUCGGUG 18 9884 BCL11A-8175 + UCCAAGUGAUGUCUCGGUG 19 9885 BCL11A-8176 + GUCCAAGUGAUGUCUCGGUG 20 9886 BCL11A-8177 + GGUCCAAGUGAUGUCUCGGUG 21 9887 BCL11A-8178 + GGGUCCAAGUGAUGUCUCGGUG 22 9888 BCL11A-8179 + GGGGUCCAAGUGAUGUCUCGGUG 23 9889 BCL11A-8180 + GGGGGUCCAAGUGAUGUCUCGGUG 24 9890 BCL11A-8181 + AGCUCCCCGGGCGGUGUG 18 9891 BCL11A-8182 + CAGCUCCCCGGGCGGUGUG 19 9892 BCL11A-8183 + CCAGCUCCCCGGGCGGUGUG 20 9893 BCL11A-8184 + UCCAGCUCCCCGGGCGGUGUG 21 9894 BCL11A-8185 + GUCCAGCUCCCCGGGCGGUGUG 22 9895 BCL11A-8186 + CGUCCAGCUCCCCGGGCGGUGUG 23 9896 BCL11A-8187 + CCGUCCAGCUCCCCGGGCGGUGUG 24 9897 BCL11A-8188 + GCCGAAUGGGGGUGUGUG 18 9898 BCL11A-8189 + CGCCGAAUGGGGGUGUGUG 19 9899 BCL11A-8190 + ACGCCGAAUGGGGGUGUGUG 20 9900 BCL11A-8191 + UACGCCGAAUGGGGGUGUGUG 21 9901 BCL11A-8192 + CUACGCCGAAUGGGGGUGUGUG 22 9902 BCL11A-8193 + ACUACGCCGAAUGGGGGUGUGUG 23 9903 BCL11A-8194 + UACUACGCCGAAUGGGGGUGUGUG 24 9904 BCL11A-8195 + GGGAGGAGGGGCGGAUUG 18 9905 BCL11A-8196 + AGGGAGGAGGGGCGGAUUG 19 9906 BCL11A-8197 + GAGGGAGGAGGGGCGGAUUG 20 9907 BCL11A-8198 + GGAGGGAGGAGGGGCGGAUUG 21 9908 BCL11A-8199 + GGGAGGGAGGAGGGGCGGAUUG 22 9909 BCL11A-8200 + UGGGAGGGAGGAGGGGCGGAUUG 23 9910 BCL11A-8201 + CUGGGAGGGAGGAGGGGCGGAUUG 24 9911 BCL11A-8202 + UCGCACAGGUUGCACUUG 18 9912 BCL11A-8203 + GUCGCACAGGUUGCACUUG 19 9913 BCL11A-8204 + GGUCGCACAGGUUGCACUUG 20 9914 BCL11A-8205 + UGGUCGCACAGGUUGCACUUG 21 9915 BCL11A-8206 + GUGGUCGCACAGGUUGCACUUG 22 9916 BCL11A-8207 + CGUGGUCGCACAGGUUGCACUUG 23 9917 BCL11A-8208 + GCGUGGUCGCACAGGUUGCACUUG 24 9918 BCL11A-8209 + ACCAGGUUGCUCUGAAAU 18 9919 BCL11A-8210 + CACCAGGUUGCUCUGAAAU 19 9920 BCL11A-8211 + CCACCAGGUUGCUCUGAAAU 20 9921 BCL11A-8212 + ACCACCAGGUUGCUCUGAAAU 21 9922 BCL11A-8213 + CACCACCAGGUUGCUCUGAAAU 22 9923 BCL11A-8214 + GCACCACCAGGUUGCUCUGAAAU 23 9924 BCL11A-8215 + UGCACCACCAGGUUGCUCUGAAAU 24 9925 BCL11A-8216 + CGGGCCCGGACCACUAAU 18 9926 BCL11A-8217 + CCGGGCCCGGACCACUAAU 19 9927 BCL11A-8218 + CCCGGGCCCGGACCACUAAU 20 9928 BCL11A-8219 + GCCCGGGCCCGGACCACUAAU 21 9929 BCL11A-8220 + UGCCCGGGCCCGGACCACUAAU 22 9930 BCL11A-8221 + CUGCCCGGGCCCGGACCACUAAU 23 9931 BCL11A-8222 + CCUGCCCGGGCCCGGACCACUAAU 24 9932 BCL11A-8223 + GGGCUCUCGAGCUUCCAU 18 9933 BCL11A-8224 + AGGGCUCUCGAGCUUCCAU 19 9934 BCL11A-8225 + AAGGGCUCUCGAGCUUCCAU 20 9935 BCL11A-8226 + UAAGGGCUCUCGAGCUUCCAU 21 9936 BCL11A-8227 + UUAAGGGCUCUCGAGCUUCCAU 22 9937 BCL11A-8228 + CUUAAGGGCUCUCGAGCUUCCAU 23 9938 BCL11A-8229 + ACUUAAGGGCUCUCGAGCUUCCAU 24 9939 BCL11A-8230 + GUCGGACUUGACCGUCAU 18 9940 BCL11A-8231 + CGUCGGACUUGACCGUCAU 19 9941 BCL11A-6186 + UCGUCGGACUUGACCGUCAU 20 9942 BCL11A-8232 + GUCGUCGGACUUGACCGUCAU 21 9943 BCL11A-8233 + CGUCGUCGGACUUGACCGUCAU 22 9944 BCL11A-8234 + CCGUCGUCGGACUUGACCGUCAU 23 9945 BCL11A-8235 + ACCGUCGUCGGACUUGACCGUCAU 24 9946 BCL11A-8236 + AUAGGGCUGGGCCGGCCU 18 9947 BCL11A-8237 + CAUAGGGCUGGGCCGGCCU 19 9948 BCL11A-6198 + GCAUAGGGCUGGGCCGGCCU 20 9949 BCL11A-8238 + UGCAUAGGGCUGGGCCGGCCU 21 9950 BCL11A-8239 + UUGCAUAGGGCUGGGCCGGCCU 22 9951 BCL11A-8240 + UUUGCAUAGGGCUGGGCCGGCCU 23 9952 BCL11A-8241 + CUUUGCAUAGGGCUGGGCCGGCCU 24 9953 BCL11A-8242 + UCUGGAGUCUCCGAAGCU 18 9954 BCL11A-8243 + GUCUGGAGUCUCCGAAGCU 19 9955 BCL11A-8244 + UGUCUGGAGUCUCCGAAGCU 20 9956 BCL11A-8245 + UUGUCUGGAGUCUCCGAAGCU 21 9957 BCL11A-8246 + AUUGUCUGGAGUCUCCGAAGCU 22 9958 BCL11A-8247 + GAUUGUCUGGAGUCUCCGAAGCU 23 9959 BCL11A-8248 + CGAUUGUCUGGAGUCUCCGAAGCU 24 9960 BCL11A-8249 + UCUCGAGCUUGAUGCGCU 18 9961 BCL11A-8250 + UUCUCGAGCUUGAUGCGCU 19 9962 BCL11A-8251 + CUUCUCGAGCUUGAUGCGCU 20 9963 BCL11A-8252 + CCUUCUCGAGCUUGAUGCGCU 21 9964 BCL11A-8253 + UCCUUCUCGAGCUUGAUGCGCU 22 9965 BCL11A-8254 + CUCCUUCUCGAGCUUGAUGCGCU 23 9966 BCL11A-8255 + ACUCCUUCUCGAGCUUGAUGCGCU 24 9967 BCL11A-8256 + UGGACUUGACCGGGGGCU 18 9968 BCL11A-8257 + UUGGACUUGACCGGGGGCU 19 9969 BCL11A-6207 + CUUGGACUUGACCGGGGGCU 20 9970 BCL11A-8258 + ACUUGGACUUGACCGGGGGCU 21 9971 BCL11A-8259 + GACUUGGACUUGACCGGGGGCU 22 9972 BCL11A-8260 + UGACUUGGACUUGACCGGGGGCU 23 9973 BCL11A-8261 + AUGACUUGGACUUGACCGGGGGCU 24 9974 BCL11A-8262 + UCCCAUGGAGAGGUGGCU 18 9975 BCL11A-8263 + AUCCCAUGGAGAGGUGGCU 19 9976 BCL11A-6208 + AAUCCCAUGGAGAGGUGGCU 20 9977 BCL11A-8264 + GAAUCCCAUGGAGAGGUGGCU 21 9978 BCL11A-8265 + UGAAUCCCAUGGAGAGGUGGCU 22 9979 BCL11A-8266 + AUGAAUCCCAUGGAGAGGUGGCU 23 9980 BCL11A-8267 + UAUGAAUCCCAUGGAGAGGUGGCU 24 9981 BCL11A-8268 + GUGCACCACCAGGUUGCU 18 9982 BCL11A-8269 + GGUGCACCACCAGGUUGCU 19 9983 BCL11A-8270 + CGGUGCACCACCAGGUUGCU 20 9984 BCL11A-8271 + CCGGUGCACCACCAGGUUGCU 21 9985 BCL11A-8272 + GCCGGUGCACCACCAGGUUGCU 22 9986 BCL11A-8273 + CGCCGGUGCACCACCAGGUUGCU 23 9987 BCL11A-8274 + GCGCCGGUGCACCACCAGGUUGCU 24 9988 BCL11A-8275 + AAGCUAAGGAAGGGAUCU 18 9989 BCL11A-8276 + GAAGCUAAGGAAGGGAUCU 19 9990 BCL11A-8277 + CGAAGCUAAGGAAGGGAUCU 20 9991 BCL11A-8278 + CCGAAGCUAAGGAAGGGAUCU 21 9992 BCL11A-8279 + UCCGAAGCUAAGGAAGGGAUCU 22 9993 BCL11A-8280 + CUCCGAAGCUAAGGAAGGGAUCU 23 9994 BCL11A-8281 + UCUCCGAAGCUAAGGAAGGGAUCU 24 9995 BCL11A-8282 + GGCGAUUGUCUGGAGUCU 18 9996 BCL11A-8283 + AGGCGAUUGUCUGGAGUCU 19 9997 BCL11A-8284 + AAGGCGAUUGUCUGGAGUCU 20 9998 BCL11A-8285 + AAAGGCGAUUGUCUGGAGUCU 21 9999 BCL11A-8286 + AAAAGGCGAUUGUCUGGAGUCU 22 10000 BCL11A-8287 + CAAAAGGCGAUUGUCUGGAGUCU 23 10001 BCL11A-8288 + GCAAAAGGCGAUUGUCUGGAGUCU 24 10002 BCL11A-8289 + CCUCCUCGUCCCCGUUCU 18 10003 BCL11A-8290 + UCCUCCUCGUCCCCGUUCU 19 10004 BCL11A-8291 + UUCCUCCUCGUCCCCGUUCU 20 10005 BCL11A-8292 + CUUCCUCCUCGUCCCCGUUCU 21 10006 BCL11A-8293 + UCUUCCUCCUCGUCCCCGUUCU 22 10007 BCL11A-8294 + CUCUUCCUCCUCGUCCCCGUUCU 23 10008 BCL11A-8295 + CCUCUUCCUCCUCGUCCCCGUUCU 24 10009 BCL11A-8296 + AGCGCAAACUCCCGUUCU 18 10010 BCL11A-8297 + AAGCGCAAACUCCCGUUCU 19 10011 BCL11A-8298 + GAAGCGCAAACUCCCGUUCU 20 10012 BCL11A-8299 + AGAAGCGCAAACUCCCGUUCU 21 10013 BCL11A-8300 + GAGAAGCGCAAACUCCCGUUCU 22 10014 BCL11A-8301 + GGAGAAGCGCAAACUCCCGUUCU 23 10015 BCL11A-8302 + UGGAGAAGCGCAAACUCCCGUUCU 24 10016 BCL11A-8303 + GGGGGCUUCAAAUUUUCU 18 10017 BCL11A-8304 + UGGGGGCUUCAAAUUUUCU 19 10018 BCL11A-8305 + CUGGGGGCUUCAAAUUUUCU 20 10019 BCL11A-8306 + CCUGGGGGCUUCAAAUUUUCU 21 10020 BCL11A-8307 + CCCUGGGGGCUUCAAAUUUUCU 22 10021 BCL11A-8308 + CCCCUGGGGGCUUCAAAUUUUCU 23 10022 BCL11A-8309 + ACCCCUGGGGGCUUCAAAUUUUCU 24 10023 BCL11A-8310 + AAGAACCUAGAAAGAGGU 18 10024 BCL11A-8311 + GAAGAACCUAGAAAGAGGU 19 10025 BCL11A-6224 + UGAAGAACCUAGAAAGAGGU 20 10026 BCL11A-8312 + GUGAAGAACCUAGAAAGAGGU 21 10027 BCL11A-8313 + UGUGAAGAACCUAGAAAGAGGU 22 10028 BCL11A-8314 + GUGUGAAGAACCUAGAAAGAGGU 23 10029 BCL11A-8315 + UGUGUGAAGAACCUAGAAAGAGGU 24 10030 BCL11A-8316 + UCCAGCUCCCCGGGCGGU 18 10031 BCL11A-8317 + GUCCAGCUCCCCGGGCGGU 19 10032 BCL11A-8318 + CGUCCAGCUCCCCGGGCGGU 20 10033 BCL11A-8319 + CCGUCCAGCUCCCCGGGCGGU 21 10034 BCL11A-8320 + UCCGUCCAGCUCCCCGGGCGGU 22 10035 BCL11A-8321 + CUCCGUCCAGCUCCCCGGGCGGU 23 10036 BCL11A-8322 + CCUCCGUCCAGCUCCCCGGGCGGU 24 10037 BCL11A-8323 + GAUACCAACCCGCGGGGU 18 10038 BCL11A-8324 + GGAUACCAACCCGCGGGGU 19 10039 BCL11A-8325 + GGGAUACCAACCCGCGGGGU 20 10040 BCL11A-8326 + AGGGAUACCAACCCGCGGGGU 21 10041 BCL11A-8327 + AAGGGAUACCAACCCGCGGGGU 22 10042 BCL11A-8328 + GAAGGGAUACCAACCCGCGGGGU 23 10043 BCL11A-8329 + UGAAGGGAUACCAACCCGCGGGGU 24 10044 BCL11A-8330 + UACGCCGAAUGGGGGUGU 18 10045 BCL11A-8331 + CUACGCCGAAUGGGGGUGU 19 10046 BCL11A-8332 + ACUACGCCGAAUGGGGGUGU 20 10047 BCL11A-8333 + UACUACGCCGAAUGGGGGUGU 21 10048 BCL11A-8334 + GUACUACGCCGAAUGGGGGUGU 22 10049 BCL11A-8335 + GGUACUACGCCGAAUGGGGGUGU 23 10050 BCL11A-8336 + GGGUACUACGCCGAAUGGGGGUGU 24 10051 BCL11A-8337 + GAGGCAAAAGGCGAUUGU 18 10052 BCL11A-8338 + GGAGGCAAAAGGCGAUUGU 19 10053 BCL11A-8339 + AGGAGGCAAAAGGCGAUUGU 20 10054 BCL11A-8340 + GAGGAGGCAAAAGGCGAUUGU 21 10055 BCL11A-8341 + CGAGGAGGCAAAAGGCGAUUGU 22 10056 BCL11A-8342 + ACGAGGAGGCAAAAGGCGAUUGU 23 10057 BCL11A-8343 + GACGAGGAGGCAAAAGGCGAUUGU 24 10058 BCL11A-8344 + CAAAUUUUCUCAGAACUU 18 10059 BCL11A-8345 + UCAAAUUUUCUCAGAACUU 19 10060 BCL11A-8346 + UUCAAAUUUUCUCAGAACUU 20 10061 BCL11A-8347 + CUUCAAAUUUUCUCAGAACUU 21 10062 BCL11A-8348 + GCUUCAAAUUUUCUCAGAACUU 22 10063 BCL11A-8349 + GGCUUCAAAUUUUCUCAGAACUU 23 10064 BCL11A-8350 + GGGCUUCAAAUUUUCUCAGAACUU 24 10065 BCL11A-8351 + CGCUGCGUCUGCCCUCUU 18 10066 BCL11A-8352 + UCGCUGCGUCUGCCCUCUU 19 10067 BCL11A-8353 + GUCGCUGCGUCUGCCCUCUU 20 10068 BCL11A-8354 + UGUCGCUGCGUCUGCCCUCUU 21 10069 BCL11A-8355 + GUGUCGCUGCGUCUGCCCUCUU 22 10070 BCL11A-8356 + AGUGUCGCUGCGUCUGCCCUCUU 23 10071 BCL11A-8357 + AAGUGUCGCUGCGUCUGCCCUCUU 24 10072 BCL11A-8358 + AGUCGCUGGUGCCGGGUU 18 10073 BCL11A-8359 + AAGUCGCUGGUGCCGGGUU 19 10074 BCL11A-8360 + CAAGUCGCUGGUGCCGGGUU 20 10075 BCL11A-8361 + CCAAGUCGCUGGUGCCGGGUU 21 10076 BCL11A-8362 + ACCAAGUCGCUGGUGCCGGGUU 22 10077 BCL11A-8363 + CACCAAGUCGCUGGUGCCGGGUU 23 10078 BCL11A-8364 + CCACCAAGUCGCUGGUGCCGGGUU 24 10079 BCL11A-8365 + CUGCCCAGCAGCAGCUUU 18 10080 BCL11A-8366 + GCUGCCCAGCAGCAGCUUU 19 10081 BCL11A-8367 + GGCUGCCCAGCAGCAGCUUU 20 10082 BCL11A-8368 + GGGCUGCCCAGCAGCAGCUUU 21 10083 BCL11A-8369 + GGGGCUGCCCAGCAGCAGCUUU 22 10084 BCL11A-8370 + UGGGGCUGCCCAGCAGCAGCUUU 23 10085 BCL11A-8371 + CUGGGGCUGCCCAGCAGCAGCUUU 24 10086 BCL11A-8372 - GGCAGGCCCAGCUCAAAA 18 10087 BCL11A-8373 - GGGCAGGCCCAGCUCAAAA 19 10088 BCL11A-8374 - CGGGCAGGCCCAGCUCAAAA 20 10089 BCL11A-8375 - CCGGGCAGGCCCAGCUCAAAA 21 10090 BCL11A-8376 - CCCGGGCAGGCCCAGCUCAAAA 22 10091 BCL11A-8377 - GCCCGGGCAGGCCCAGCUCAAAA 23 10092 BCL11A-8378 - GGCCCGGGCAGGCCCAGCUCAAAA 24 10093 BCL11A-8379 - UAAGAAUCUACUUAGAAA 18 10094 BCL11A-8380 - UUAAGAAUCUACUUAGAAA 19 10095 BCL11A-8381 - AUUAAGAAUCUACUUAGAAA 20 10096 BCL11A-8382 - GAUUAAGAAUCUACUUAGAAA 21 10097 BCL11A-8383 - GGAUUAAGAAUCUACUUAGAAA 22 10098 BCL11A-8384 - UGGAUUAAGAAUCUACUUAGAAA 23 10099 BCL11A-8385 - AUGGAUUAAGAAUCUACUUAGAAA 24 10100 BCL11A-8386 - CGGGCAGGCCCAGCUCAA 18 10101 BCL11A-8387 - CCGGGCAGGCCCAGCUCAA 19 10102 BCL11A-8388 - CCCGGGCAGGCCCAGCUCAA 20 10103 BCL11A-8389 - GCCCGGGCAGGCCCAGCUCAA 21 10104 BCL11A-8390 - GGCCCGGGCAGGCCCAGCUCAA 22 10105 BCL11A-8391 - GGGCCCGGGCAGGCCCAGCUCAA 23 10106 BCL11A-8392 - CGGGCCCGGGCAGGCCCAGCUCAA 24 10107 BCL11A-8393 - GACGAGGAAGAGGAAGAA 18 10108 BCL11A-8394 - CGACGAGGAAGAGGAAGAA 19 10109 BCL11A-3947 - ACGACGAGGAAGAGGAAGAA 20 10110 BCL11A-8395 - GACGACGAGGAAGAGGAAGAA 21 10111 BCL11A-8396 - GGACGACGAGGAAGAGGAAGAA 22 10112 BCL11A-8397 - AGGACGACGAGGAAGAGGAAGAA 23 10113 BCL11A-8398 - GAGGACGACGAGGAAGAGGAAGAA 24 10114 BCL11A-8399 - CAACCUGAUCCCGGAGAA 18 10115 BCL11A-8400 - CCAACCUGAUCCCGGAGAA 19 10116 BCL11A-5881 - CCCAACCUGAUCCCGGAGAA 20 10117 BCL11A-8401 - CCCCAACCUGAUCCCGGAGAA 21 10118 BCL11A-8402 - ACCCCAACCUGAUCCCGGAGAA 22 10119 BCL11A-8403 - GACCCCAACCUGAUCCCGGAGAA 23 10120 BCL11A-8404 - CGACCCCAACCUGAUCCCGGAGAA 24 10121 BCL11A-8405 - GGAGCACUCCUCGGAGAA 18 10122 BCL11A-8406 - CGGAGCACUCCUCGGAGAA 19 10123 BCL11A-5882 - UCGGAGCACUCCUCGGAGAA 20 10124 BCL11A-8407 - GUCGGAGCACUCCUCGGAGAA 21 10125 BCL11A-8408 - CGUCGGAGCACUCCUCGGAGAA 22 10126 BCL11A-8409 - UCGUCGGAGCACUCCUCGGAGAA 23 10127 BCL11A-8410 - CUCGUCGGAGCACUCCUCGGAGAA 24 10128 BCL11A-8411 - GAGGAGGACGACGAGGAA 18 10129 BCL11A-8412 - AGAGGAGGACGACGAGGAA 19 10130 BCL11A-3950 - AAGAGGAGGACGACGAGGAA 20 10131 BCL11A-8413 - GAAGAGGAGGACGACGAGGAA 21 10132 BCL11A-8414 - GGAAGAGGAGGACGACGAGGAA 22 10133 BCL11A-8415 - AGGAAGAGGAGGACGACGAGGAA 23 10134 BCL11A-8416 - GAGGAAGAGGAGGACGACGAGGAA 24 10135 BCL11A-8417 - GAGGAAGAAGAGGAGGAA 18 10136 BCL11A-8418 - AGAGGAAGAAGAGGAGGAA 19 10137 BCL11A-3962 - AAGAGGAAGAAGAGGAGGAA 20 10138 BCL11A-8419 - GAAGAGGAAGAAGAGGAGGAA 21 10139 BCL11A-8420 - GGAAGAGGAAGAAGAGGAGGAA 22 10140 BCL11A-8421 - AGGAAGAGGAAGAAGAGGAGGAA 23 10141 BCL11A-8422 - GAGGAAGAGGAAGAAGAGGAGGAA 24 10142 BCL11A-8423 - AACGGGGACGAGGAGGAA 18 10143 BCL11A-8424 - GAACGGGGACGAGGAGGAA 19 10144 BCL11A-3934 - AGAACGGGGACGAGGAGGAA 20 10145 BCL11A-8425 - GAGAACGGGGACGAGGAGGAA 21 10146 BCL11A-8426 - GGAGAACGGGGACGAGGAGGAA 22 10147 BCL11A-8427 - CGGAGAACGGGGACGAGGAGGAA 23 10148 BCL11A-8428 - CCGGAGAACGGGGACGAGGAGGAA 24 10149 BCL11A-8429 - GGCGCAGCGGCACGGGAA 18 10150 BCL11A-8430 - GGGCGCAGCGGCACGGGAA 19 10151 BCL11A-3857 - GGGGCGCAGCGGCACGGGAA 20 10152 BCL11A-8431 - CGGGGCGCAGCGGCACGGGAA 21 10153 BCL11A-8432 - UCGGGGCGCAGCGGCACGGGAA 22 10154 BCL11A-8433 - CUCGGGGCGCAGCGGCACGGGAA 23 10155 BCL11A-8434 - UCUCGGGGCGCAGCGGCACGGGAA 24 10156 BCL11A-8435 - CGGCCGCGAUGCCCAACA 18 10157 BCL11A-8436 - CCGGCCGCGAUGCCCAACA 19 10158 BCL11A-5893 - CCCGGCCGCGAUGCCCAACA 20 10159 BCL11A-8437 - CCCCGGCCGCGAUGCCCAACA 21 10160 BCL11A-8438 - CCCCCGGCCGCGAUGCCCAACA 22 10161 BCL11A-8439 - GCCCCCGGCCGCGAUGCCCAACA 23 10162 BCL11A-8440 - UGCCCCCGGCCGCGAUGCCCAACA 24 10163 BCL11A-8441 - CUACUUAGAAAGCGAACA 18 10164 BCL11A-8442 - UCUACUUAGAAAGCGAACA 19 10165 BCL11A-5894 - AUCUACUUAGAAAGCGAACA 20 10166 BCL11A-8443 - AAUCUACUUAGAAAGCGAACA 21 10167 BCL11A-8444 - GAAUCUACUUAGAAAGCGAACA 22 10168 BCL11A-8445 - AGAAUCUACUUAGAAAGCGAACA 23 10169 BCL11A-8446 - AAGAAUCUACUUAGAAAGCGAACA 24 10170 BCL11A-8447 - CCCCUGUUUAGUCCACCA 18 10171 BCL11A-8448 - CCCCCUGUUUAGUCCACCA 19 10172 BCL11A-8449 - CCCCCCUGUUUAGUCCACCA 20 10173 BCL11A-8450 - CCCCCCCUGUUUAGUCCACCA 21 10174 BCL11A-8451 - UCCCCCCCUGUUUAGUCCACCA 22 10175 BCL11A-8452 - CUCCCCCCCUGUUUAGUCCACCA 23 10176 BCL11A-8453 - ACUCCCCCCCUGUUUAGUCCACCA 24 10177 BCL11A-8454 - CAUUCGGCGUAGUACCCA 18 10178 BCL11A-8455 - CCAUUCGGCGUAGUACCCA 19 10179 BCL11A-8456 - CCCAUUCGGCGUAGUACCCA 20 10180 BCL11A-8457 - CCCCAUUCGGCGUAGUACCCA 21 10181 BCL11A-8458 - CCCCCAUUCGGCGUAGUACCCA 22 10182 BCL11A-8459 - ACCCCCAUUCGGCGUAGUACCCA 23 10183 BCL11A-8460 - CACCCCCAUUCGGCGUAGUACCCA 24 10184 BCL11A-8461 - GGCCGAGGCCGAGGGCCA 18 10185 BCL11A-8462 - UGGCCGAGGCCGAGGGCCA 19 10186 BCL11A-8463 - CUGGCCGAGGCCGAGGGCCA 20 10187 BCL11A-8464 - CCUGGCCGAGGCCGAGGGCCA 21 10188 BCL11A-8465 - ACCUGGCCGAGGCCGAGGGCCA 22 10189 BCL11A-8466 - CACCUGGCCGAGGCCGAGGGCCA 23 10190 BCL11A-8467 - CCACCUGGCCGAGGCCGAGGGCCA 24 10191 BCL11A-8468 - UUUCUCUUGCAACACGCA 18 10192 BCL11A-8469 - GUUUCUCUUGCAACACGCA 19 10193 BCL11A-8470 - GGUUUCUCUUGCAACACGCA 20 10194 BCL11A-8471 - UGGUUUCUCUUGCAACACGCA 21 10195 BCL11A-8472 - AUGGUUUCUCUUGCAACACGCA 22 10196 BCL11A-8473 - CAUGGUUUCUCUUGCAACACGCA 23 10197 BCL11A-8474 - GCAUGGUUUCUCUUGCAACACGCA 24 10198 BCL11A-8475 - ACUUGGACCCCCACCGCA 18 10199 BCL11A-8476 - CACUUGGACCCCCACCGCA 19 10200 BCL11A-8477 - UCACUUGGACCCCCACCGCA 20 10201 BCL11A-8478 - AUCACUUGGACCCCCACCGCA 21 10202 BCL11A-8479 - CAUCACUUGGACCCCCACCGCA 22 10203 BCL11A-8480 - ACAUCACUUGGACCCCCACCGCA 23 10204 BCL11A-8481 - GACAUCACUUGGACCCCCACCGCA 24 10205 BCL11A-8482 - UCUCGGGGCGCAGCGGCA 18 10206 BCL11A-8483 - AUCUCGGGGCGCAGCGGCA 19 10207 BCL11A-5904 - GAUCUCGGGGCGCAGCGGCA 20 10208 BCL11A-8484 - GGAUCUCGGGGCGCAGCGGCA 21 10209 BCL11A-8485 - GGGAUCUCGGGGCGCAGCGGCA 22 10210 BCL11A-8486 - AGGGAUCUCGGGGCGCAGCGGCA 23 10211 BCL11A-8487 - GAGGGAUCUCGGGGCGCAGCGGCA 24 10212 BCL11A-8488 - AGACUUAGAGAGCUGGCA 18 10213 BCL11A-8489 - GAGACUUAGAGAGCUGGCA 19 10214 BCL11A-5907 - GGAGACUUAGAGAGCUGGCA 20 10215 BCL11A-8490 - AGGAGACUUAGAGAGCUGGCA 21 10216 BCL11A-8491 - UAGGAGACUUAGAGAGCUGGCA 22 10217 BCL11A-8492 - CUAGGAGACUUAGAGAGCUGGCA 23 10218 BCL11A-8493 - UCUAGGAGACUUAGAGAGCUGGCA 24 10219 BCL11A-8494 - GCUCCAUGCAGCACUUCA 18 10220 BCL11A-8495 - AGCUCCAUGCAGCACUUCA 19 10221 BCL11A-8496 - CAGCUCCAUGCAGCACUUCA 20 10222 BCL11A-8497 - UCAGCUCCAUGCAGCACUUCA 21 10223 BCL11A-8498 - CUCAGCUCCAUGCAGCACUUCA 22 10224 BCL11A-8499 - GCUCAGCUCCAUGCAGCACUUCA 23 10225 BCL11A-8500 - UGCUCAGCUCCAUGCAGCACUUCA 24 10226 BCL11A-8501 - UGGUGGCCAAGUUCAAGA 18 10227 BCL11A-8502 - GUGGUGGCCAAGUUCAAGA 19 10228 BCL11A-8503 - CGUGGUGGCCAAGUUCAAGA 20 10229 BCL11A-8504 - CCGUGGUGGCCAAGUUCAAGA 21 10230 BCL11A-8505 - UCCGUGGUGGCCAAGUUCAAGA 22 10231 BCL11A-8506 - GUCCGUGGUGGCCAAGUUCAAGA 23 10232 BCL11A-8507 - AGUCCGUGGUGGCCAAGUUCAAGA 24 10233 BCL11A-8508 - AGGAGGAGCUGACGGAGA 18 10234 BCL11A-8509 - GAGGAGGAGCUGACGGAGA 19 10235 BCL11A-8510 - GGAGGAGGAGCUGACGGAGA 20 10236 BCL11A-8511 - AGGAGGAGGAGCUGACGGAGA 21 10237 BCL11A-8512 - GAGGAGGAGGAGCUGACGGAGA 22 10238 BCL11A-8513 - GGAGGAGGAGGAGCUGACGGAGA 23 10239 BCL11A-8514 - AGGAGGAGGAGGAGCUGACGGAGA 24 10240 BCL11A-8515 - CCAACCUGAUCCCGGAGA 18 10241 BCL11A-8516 - CCCAACCUGAUCCCGGAGA 19 10242 BCL11A-8517 - CCCCAACCUGAUCCCGGAGA 20 10243 BCL11A-8518 - ACCCCAACCUGAUCCCGGAGA 21 10244 BCL11A-8519 - GACCCCAACCUGAUCCCGGAGA 22 10245 BCL11A-8520 - CGACCCCAACCUGAUCCCGGAGA 23 10246 BCL11A-8521 - ACGACCCCAACCUGAUCCCGGAGA 24 10247 BCL11A-8522 - CGGAGCACUCCUCGGAGA 18 10248 BCL11A-8523 - UCGGAGCACUCCUCGGAGA 19 10249 BCL11A-8524 - GUCGGAGCACUCCUCGGAGA 20 10250 BCL11A-8525 - CGUCGGAGCACUCCUCGGAGA 21 10251 BCL11A-8526 - UCGUCGGAGCACUCCUCGGAGA 22 10252 BCL11A-8527 - CUCGUCGGAGCACUCCUCGGAGA 23 10253 BCL11A-8528 - CCUCGUCGGAGCACUCCUCGGAGA 24 10254 BCL11A-8529 - UACCAGGAUCAGUAUCGA 18 10255 BCL11A-8530 - AUACCAGGAUCAGUAUCGA 19 10256 BCL11A-8531 - AAUACCAGGAUCAGUAUCGA 20 10257 BCL11A-8532 - GAAUACCAGGAUCAGUAUCGA 21 10258 BCL11A-8533 - AGAAUACCAGGAUCAGUAUCGA 22 10259 BCL11A-8534 - AAGAAUACCAGGAUCAGUAUCGA 23 10260 BCL11A-8535 - UAAGAAUACCAGGAUCAGUAUCGA 24 10261 BCL11A-8536 - UGUGUGGCAGUUUUCGGA 18 10262 BCL11A-8537 - AUGUGUGGCAGUUUUCGGA 19 10263 BCL11A-5929 - GAUGUGUGGCAGUUUUCGGA 20 10264 BCL11A-8538 - AGAUGUGUGGCAGUUUUCGGA 21 10265 BCL11A-8539 - AAGAUGUGUGGCAGUUUUCGGA 22 10266 BCL11A-8540 - CAAGAUGUGUGGCAGUUUUCGGA 23 10267 BCL11A-8541 - UCAAGAUGUGUGGCAGUUUUCGGA 24 10268 BCL11A-8542 - ACCGCCCGGGGAGCUGGA 18 10269 BCL11A-8543 - CACCGCCCGGGGAGCUGGA 19 10270 BCL11A-5933 - ACACCGCCCGGGGAGCUGGA 20 10271 BCL11A-8544 - CACACCGCCCGGGGAGCUGGA 21 10272 BCL11A-8545 - CCACACCGCCCGGGGAGCUGGA 22 10273 BCL11A-8546 - UCCACACCGCCCGGGGAGCUGGA 23 10274 BCL11A-8547 - CUCCACACCGCCCGGGGAGCUGGA 24 10275 BCL11A-8548 - AGCGGCACGGGAAGUGGA 18 10276 BCL11A-8549 - CAGCGGCACGGGAAGUGGA 19 10277 BCL11A-5934 - GCAGCGGCACGGGAAGUGGA 20 10278 BCL11A-8550 - CGCAGCGGCACGGGAAGUGGA 21 10279 BCL11A-8551 - GCGCAGCGGCACGGGAAGUGGA 22 10280 BCL11A-8552 - GGCGCAGCGGCACGGGAAGUGGA 23 10281 BCL11A-8553 - GGGCGCAGCGGCACGGGAAGUGGA 24 10282 BCL11A-8554 - AGGAGGAGGAGGAGCUGA 18 10283 BCL11A-8555 - GAGGAGGAGGAGGAGCUGA 19 10284 BCL11A-5938 - AGAGGAGGAGGAGGAGCUGA 20 10285 BCL11A-8556 - AAGAGGAGGAGGAGGAGCUGA 21 10286 BCL11A-8557 - GAAGAGGAGGAGGAGGAGCUGA 22 10287 BCL11A-8558 - GGAAGAGGAGGAGGAGGAGCUGA 23 10288 BCL11A-8559 - AGGAAGAGGAGGAGGAGGAGCUGA 24 10289 BCL11A-8560 - GGUUGAAUCCAAUGGCUA 18 10290 BCL11A-8561 - CGGUUGAAUCCAAUGGCUA 19 10291 BCL11A-5944 - GCGGUUGAAUCCAAUGGCUA 20 10292 BCL11A-8562 - UGCGGUUGAAUCCAAUGGCUA 21 10293 BCL11A-8563 - CUGCGGUUGAAUCCAAUGGCUA 22 10294 BCL11A-8564 - GCUGCGGUUGAAUCCAAUGGCUA 23 10295 BCL11A-8565 - UGCUGCGGUUGAAUCCAAUGGCUA 24 10296 BCL11A-8566 - AGAAUACCAGGAUCAGUA 18 10297 BCL11A-8567 - AAGAAUACCAGGAUCAGUA 19 10298 BCL11A-8568 - UAAGAAUACCAGGAUCAGUA 20 10299 BCL11A-8569 - CUAAGAAUACCAGGAUCAGUA 21 10300 BCL11A-8570 - GCUAAGAAUACCAGGAUCAGUA 22 10301 BCL11A-8571 - UGCUAAGAAUACCAGGAUCAGUA 23 10302 BCL11A-8572 - CUGCUAAGAAUACCAGGAUCAGUA 24 10303 BCL11A-8573 - AUUUCUCUAGGAGACUUA 18 10304 BCL11A-8574 - GAUUUCUCUAGGAGACUUA 19 10305 BCL11A-8575 - GGAUUUCUCUAGGAGACUUA 20 10306 BCL11A-8576 - UGGAUUUCUCUAGGAGACUUA 21 10307 BCL11A-8577 - AUGGAUUUCUCUAGGAGACUUA 22 10308 BCL11A-8578 - CAUGGAUUUCUCUAGGAGACUUA 23 10309 BCL11A-8579 - CCAUGGAUUUCUCUAGGAGACUUA 24 10310 BCL11A-8580 - CCGGCCGCGAUGCCCAAC 18 10311 BCL11A-8581 - CCCGGCCGCGAUGCCCAAC 19 10312 BCL11A-8582 - CCCCGGCCGCGAUGCCCAAC 20 10313 BCL11A-8583 - CCCCCGGCCGCGAUGCCCAAC 21 10314 BCL11A-8584 - GCCCCCGGCCGCGAUGCCCAAC 22 10315 BCL11A-8585 - UGCCCCCGGCCGCGAUGCCCAAC 23 10316 BCL11A-8586 - CUGCCCCCGGCCGCGAUGCCCAAC 24 10317 BCL11A-8587 - AACCUGAUCCCGGAGAAC 18 10318 BCL11A-8588 - CAACCUGAUCCCGGAGAAC 19 10319 BCL11A-5948 - CCAACCUGAUCCCGGAGAAC 20 10320 BCL11A-8589 - CCCAACCUGAUCCCGGAGAAC 21 10321 BCL11A-8590 - CCCCAACCUGAUCCCGGAGAAC 22 10322 BCL11A-8591 - ACCCCAACCUGAUCCCGGAGAAC 23 10323 BCL11A-8592 - GACCCCAACCUGAUCCCGGAGAAC 24 10324 BCL11A-8593 - UCUACUUAGAAAGCGAAC 18 10325 BCL11A-8594 - AUCUACUUAGAAAGCGAAC 19 10326 BCL11A-8595 - AAUCUACUUAGAAAGCGAAC 20 10327 BCL11A-8596 - GAAUCUACUUAGAAAGCGAAC 21 10328 BCL11A-8597 - AGAAUCUACUUAGAAAGCGAAC 22 10329 BCL11A-8598 - AAGAAUCUACUUAGAAAGCGAAC 23 10330 BCL11A-8599 - UAAGAAUCUACUUAGAAAGCGAAC 24 10331 BCL11A-8600 - GAGGCGGCGCGCCACCAC 18 10332 BCL11A-8601 - GGAGGCGGCGCGCCACCAC 19 10333 BCL11A-8602 - UGGAGGCGGCGCGCCACCAC 20 10334 BCL11A-8603 - CUGGAGGCGGCGCGCCACCAC 21 10335 BCL11A-8604 - CCUGGAGGCGGCGCGCCACCAC 22 10336 BCL11A-8605 - GCCUGGAGGCGGCGCGCCACCAC 23 10337 BCL11A-8606 - AGCCUGGAGGCGGCGCGCCACCAC 24 10338 BCL11A-8607 - GUGCACCGGCGCAGCCAC 18 10339 BCL11A-8608 - GGUGCACCGGCGCAGCCAC 19 10340 BCL11A-8609 - UGGUGCACCGGCGCAGCCAC 20 10341 BCL11A-8610 - GUGGUGCACCGGCGCAGCCAC 21 10342 BCL11A-8611 - GGUGGUGCACCGGCGCAGCCAC 22 10343 BCL11A-8612 - UGGUGGUGCACCGGCGCAGCCAC 23 10344 BCL11A-8613 - CUGGUGGUGCACCGGCGCAGCCAC 24 10345 BCL11A-8614 - AGCAAGCUGAAGCGCCAC 18 10346 BCL11A-8615 - CAGCAAGCUGAAGCGCCAC 19 10347 BCL11A-8616 - CCAGCAAGCUGAAGCGCCAC 20 10348 BCL11A-8617 - GCCAGCAAGCUGAAGCGCCAC 21 10349 BCL11A-8618 - GGCCAGCAAGCUGAAGCGCCAC 22 10350 BCL11A-8619 - AGGCCAGCAAGCUGAAGCGCCAC 23 10351 BCL11A-8620 - CAGGCCAGCAAGCUGAAGCGCCAC 24 10352 BCL11A-8621 - GCCGAGGCCGAGGGCCAC 18 10353 BCL11A-8622 - GGCCGAGGCCGAGGGCCAC 19 10354 BCL11A-5951 - UGGCCGAGGCCGAGGGCCAC 20 10355 BCL11A-8623 - CUGGCCGAGGCCGAGGGCCAC 21 10356 BCL11A-8624 - CCUGGCCGAGGCCGAGGGCCAC 22 10357 BCL11A-8625 - ACCUGGCCGAGGCCGAGGGCCAC 23 10358 BCL11A-8626 - CACCUGGCCGAGGCCGAGGGCCAC 24 10359 BCL11A-8627 - CUCGGGGCGCAGCGGCAC 18 10360 BCL11A-8628 - UCUCGGGGCGCAGCGGCAC 19 10361 BCL11A-5953 - AUCUCGGGGCGCAGCGGCAC 20 10362 BCL11A-8629 - GAUCUCGGGGCGCAGCGGCAC 21 10363 BCL11A-8630 - GGAUCUCGGGGCGCAGCGGCAC 22 10364 BCL11A-8631 - GGGAUCUCGGGGCGCAGCGGCAC 23 10365 BCL11A-8632 - AGGGAUCUCGGGGCGCAGCGGCAC 24 10366 BCL11A-8633 - CCACCACCGAGACAUCAC 18 10367 BCL11A-8634 - UCCACCACCGAGACAUCAC 19 10368 BCL11A-8635 - GUCCACCACCGAGACAUCAC 20 10369 BCL11A-8636 - AGUCCACCACCGAGACAUCAC 21 10370 BCL11A-8637 - UAGUCCACCACCGAGACAUCAC 22 10371 BCL11A-8638 - UUAGUCCACCACCGAGACAUCAC 23 10372 BCL11A-8639 - UUUAGUCCACCACCGAGACAUCAC 24 10373 BCL11A-8640 - GAGGAAGAGGAGGACGAC 18 10374 BCL11A-8641 - GGAGGAAGAGGAGGACGAC 19 10375 BCL11A-3949 - AGGAGGAAGAGGAGGACGAC 20 10376 BCL11A-8642 - GAGGAGGAAGAGGAGGACGAC 21 10377 BCL11A-8643 - CGAGGAGGAAGAGGAGGACGAC 22 10378 BCL11A-8644 - ACGAGGAGGAAGAGGAGGACGAC 23 10379 BCL11A-8645 - GACGAGGAGGAAGAGGAGGACGAC 24 10380 BCL11A-8646 - GUCGUGGGCGUGGGCGAC 18 10381 BCL11A-8647 - GGUCGUGGGCGUGGGCGAC 19 10382 BCL11A-8648 - CGGUCGUGGGCGUGGGCGAC 20 10383 BCL11A-8649 - GCGGUCGUGGGCGUGGGCGAC 21 10384 BCL11A-8650 - CGCGGUCGUGGGCGUGGGCGAC 22 10385 BCL11A-8651 - GCGCGGUCGUGGGCGUGGGCGAC 23 10386 BCL11A-8652 - GGCGCGGUCGUGGGCGUGGGCGAC 24 10387 BCL11A-8653 - AUCCCGGAGAACGGGGAC 18 10388 BCL11A-8654 - GAUCCCGGAGAACGGGGAC 19 10389 BCL11A-8655 - UGAUCCCGGAGAACGGGGAC 20 10390 BCL11A-8656 - CUGAUCCCGGAGAACGGGGAC 21 10391 BCL11A-8657 - CCUGAUCCCGGAGAACGGGGAC 22 10392 BCL11A-8658 - ACCUGAUCCCGGAGAACGGGGAC 23 10393 BCL11A-8659 - AACCUGAUCCCGGAGAACGGGGAC 24 10394 BCL11A-8660 - UGGAGGCGGCGCGCCACC 18 10395 BCL11A-8661 - CUGGAGGCGGCGCGCCACC 19 10396 BCL11A-8662 - CCUGGAGGCGGCGCGCCACC 20 10397 BCL11A-8663 - GCCUGGAGGCGGCGCGCCACC 21 10398 BCL11A-8664 - AGCCUGGAGGCGGCGCGCCACC 22 10399 BCL11A-8665 - GAGCCUGGAGGCGGCGCGCCACC 23 10400 BCL11A-8666 - UGAGCCUGGAGGCGGCGCGCCACC 24 10401 BCL11A-8667 - CCCAUUCGGCGUAGUACC 18 10402 BCL11A-8668 - CCCCAUUCGGCGUAGUACC 19 10403 BCL11A-8669 - CCCCCAUUCGGCGUAGUACC 20 10404 BCL11A-8670 - ACCCCCAUUCGGCGUAGUACC 21 10405 BCL11A-8671 - CACCCCCAUUCGGCGUAGUACC 22 10406 BCL11A-8672 - ACACCCCCAUUCGGCGUAGUACC 23 10407 BCL11A-8673 - CACACCCCCAUUCGGCGUAGUACC 24 10408 BCL11A-8674 - GAGAAAAUUUGAAGCCCC 18 10409 BCL11A-8675 - UGAGAAAAUUUGAAGCCCC 19 10410 BCL11A-8676 - CUGAGAAAAUUUGAAGCCCC 20 10411 BCL11A-8677 - UCUGAGAAAAUUUGAAGCCCC 21 10412 BCL11A-8678 - UUCUGAGAAAAUUUGAAGCCCC 22 10413 BCL11A-8679 - GUUCUGAGAAAAUUUGAAGCCCC 23 10414 BCL11A-8680 - AGUUCUGAGAAAAUUUGAAGCCCC 24 10415 BCL11A-8681 - CGCUUCUCCACACCGCCC 18 10416 BCL11A-8682 - GCGCUUCUCCACACCGCCC 19 10417 BCL11A-5976 - UGCGCUUCUCCACACCGCCC 20 10418 BCL11A-8683 - UUGCGCUUCUCCACACCGCCC 21 10419 BCL11A-8684 - UUUGCGCUUCUCCACACCGCCC 22 10420 BCL11A-8685 - GUUUGCGCUUCUCCACACCGCCC 23 10421 BCL11A-8686 - AGUUUGCGCUUCUCCACACCGCCC 24 10422 BCL11A-8687 - UCUCCACCGCCAGCUCCC 18 10423 BCL11A-8688 - CUCUCCACCGCCAGCUCCC 19 10424 BCL11A-5982 - UCUCUCCACCGCCAGCUCCC 20 10425 BCL11A-8689 - GUCUCUCCACCGCCAGCUCCC 21 10426 BCL11A-8690 - GGUCUCUCCACCGCCAGCUCCC 22 10427 BCL11A-8691 - CGGUCUCUCCACCGCCAGCUCCC 23 10428 BCL11A-8692 - ACGGUCUCUCCACCGCCAGCUCCC 24 10429 BCL11A-8693 - ACGGCUUCGGGCUGAGCC 18 10430 BCL11A-8694 - UACGGCUUCGGGCUGAGCC 19 10431 BCL11A-5986 - CUACGGCUUCGGGCUGAGCC 20 10432 BCL11A-8695 - ACUACGGCUUCGGGCUGAGCC 21 10433 BCL11A-8696 - GACUACGGCUUCGGGCUGAGCC 22 10434 BCL11A-8697 - GGACUACGGCUUCGGGCUGAGCC 23 10435 BCL11A-8698 - UGGACUACGGCUUCGGGCUGAGCC 24 10436 BCL11A-8699 - GCGCUUCUCCACACCGCC 18 10437 BCL11A-8700 - UGCGCUUCUCCACACCGCC 19 10438 BCL11A-5987 - UUGCGCUUCUCCACACCGCC 20 10439 BCL11A-8701 - UUUGCGCUUCUCCACACCGCC 21 10440 BCL11A-8702 - GUUUGCGCUUCUCCACACCGCC 22 10441 BCL11A-8703 - AGUUUGCGCUUCUCCACACCGCC 23 10442 BCL11A-8704 - GAGUUUGCGCUUCUCCACACCGCC 24 10443 BCL11A-8705 - CCCACCGCAUAGAGCGCC 18 10444 BCL11A-8706 - CCCCACCGCAUAGAGCGCC 19 10445 BCL11A-5988 - CCCCCACCGCAUAGAGCGCC 20 10446 BCL11A-8707 - ACCCCCACCGCAUAGAGCGCC 21 10447 BCL11A-8708 - GACCCCCACCGCAUAGAGCGCC 22 10448 BCL11A-8709 - GGACCCCCACCGCAUAGAGCGCC 23 10449 BCL11A-8710 - UGGACCCCCACCGCAUAGAGCGCC 24 10450 BCL11A-8711 - GGCCACCUGGCCGAGGCC 18 10451 BCL11A-8712 - CGGCCACCUGGCCGAGGCC 19 10452 BCL11A-8713 - GCGGCCACCUGGCCGAGGCC 20 10453 BCL11A-8714 - CGCGGCCACCUGGCCGAGGCC 21 10454 BCL11A-8715 - GCGCGGCCACCUGGCCGAGGCC 22 10455 BCL11A-8716 - AGCGCGGCCACCUGGCCGAGGCC 23 10456 BCL11A-8717 - AAGCGCGGCCACCUGGCCGAGGCC 24 10457 BCL11A-8718 - UCCCCGGGCGAGUCGGCC 18 10458 BCL11A-8719 - CUCCCCGGGCGAGUCGGCC 19 10459 BCL11A-8720 - GCUCCCCGGGCGAGUCGGCC 20 10460 BCL11A-8721 - UGCUCCCCGGGCGAGUCGGCC 21 10461 BCL11A-8722 - CUGCUCCCCGGGCGAGUCGGCC 22 10462 BCL11A-8723 - GCUGCUCCCCGGGCGAGUCGGCC 23 10463 BCL11A-8724 - GGCUGCUCCCCGGGCGAGUCGGCC 24 10464 BCL11A-8725 - ACGACCCCAACCUGAUCC 18 10465 BCL11A-8726 - AACGACCCCAACCUGAUCC 19 10466 BCL11A-6004 - GAACGACCCCAACCUGAUCC 20 10467 BCL11A-8727 - AGAACGACCCCAACCUGAUCC 21 10468 BCL11A-8728 - GAGAACGACCCCAACCUGAUCC 22 10469 BCL11A-8729 - CGAGAACGACCCCAACCUGAUCC 23 10470 BCL11A-8730 - GCGAGAACGACCCCAACCUGAUCC 24 10471 BCL11A-8731 - UCCUCGUCGGAGCACUCC 18 10472 BCL11A-8732 - CUCCUCGUCGGAGCACUCC 19 10473 BCL11A-8733 - CCUCCUCGUCGGAGCACUCC 20 10474 BCL11A-8734 - GCCUCCUCGUCGGAGCACUCC 21 10475 BCL11A-8735 - UGCCUCCUCGUCGGAGCACUCC 22 10476 BCL11A-8736 - UUGCCUCCUCGUCGGAGCACUCC 23 10477 BCL11A-8737 - UUUGCCUCCUCGUCGGAGCACUCC 24 10478 BCL11A-8738 - CUCUCCACCGCCAGCUCC 18 10479 BCL11A-8739 - UCUCUCCACCGCCAGCUCC 19 10480 BCL11A-8740 - GUCUCUCCACCGCCAGCUCC 20 10481 BCL11A-8741 - GGUCUCUCCACCGCCAGCUCC 21 10482 BCL11A-8742 - CGGUCUCUCCACCGCCAGCUCC 22 10483 BCL11A-8743 - ACGGUCUCUCCACCGCCAGCUCC 23 10484 BCL11A-8744 - GACGGUCUCUCCACCGCCAGCUCC 24 10485 BCL11A-8745 - AAUGGCCGCGGCUGCUCC 18 10486 BCL11A-8746 - UAAUGGCCGCGGCUGCUCC 19 10487 BCL11A-8747 - UUAAUGGCCGCGGCUGCUCC 20 10488 BCL11A-8748 - GUUAAUGGCCGCGGCUGCUCC 21 10489 BCL11A-8749 - UGUUAAUGGCCGCGGCUGCUCC 22 10490 BCL11A-8750 - CUGUUAAUGGCCGCGGCUGCUCC 23 10491 BCL11A-8751 - ACUGUUAAUGGCCGCGGCUGCUCC 24 10492 BCL11A-8752 - CUUCCCAGCCACCUCUCC 18 10493 BCL11A-8753 - CCUUCCCAGCCACCUCUCC 19 10494 BCL11A-8754 - UCCUUCCCAGCCACCUCUCC 20 10495 BCL11A-8755 - GUCCUUCCCAGCCACCUCUCC 21 10496 BCL11A-8756 - UGUCCUUCCCAGCCACCUCUCC 22 10497 BCL11A-8757 - AUGUCCUUCCCAGCCACCUCUCC 23 10498 BCL11A-8758 - AAUGUCCUUCCCAGCCACCUCUCC 24 10499 BCL11A-8759 - UCUCUAAGCGCAUCAAGC 18 10500 BCL11A-8760 - UUCUCUAAGCGCAUCAAGC 19 10501 BCL11A-8761 - CUUCUCUAAGCGCAUCAAGC 20 10502 BCL11A-8762 - CCUUCUCUAAGCGCAUCAAGC 21 10503 BCL11A-8763 - CCCUUCUCUAAGCGCAUCAAGC 22 10504 BCL11A-8764 - CCCCUUCUCUAAGCGCAUCAAGC 23 10505 BCL11A-8765 - GCCCCUUCUCUAAGCGCAUCAAGC 24 10506 BCL11A-8766 - CAGUUUUCGGAUGGAAGC 18 10507 BCL11A-8767 - GCAGUUUUCGGAUGGAAGC 19 10508 BCL11A-8768 - GGCAGUUUUCGGAUGGAAGC 20 10509 BCL11A-8769 - UGGCAGUUUUCGGAUGGAAGC 21 10510 BCL11A-8770 - GUGGCAGUUUUCGGAUGGAAGC 22 10511 BCL11A-8771 - UGUGGCAGUUUUCGGAUGGAAGC 23 10512 BCL11A-8772 - GUGUGGCAGUUUUCGGAUGGAAGC 24 10513 BCL11A-8773 - GUGGCCAAGUUCAAGAGC 18 10514 BCL11A-8774 - GGUGGCCAAGUUCAAGAGC 19 10515 BCL11A-8775 - UGGUGGCCAAGUUCAAGAGC 20 10516 BCL11A-8776 - GUGGUGGCCAAGUUCAAGAGC 21 10517 BCL11A-8777 - CGUGGUGGCCAAGUUCAAGAGC 22 10518 BCL11A-8778 - CCGUGGUGGCCAAGUUCAAGAGC 23 10519 BCL11A-8779 - UCCGUGGUGGCCAAGUUCAAGAGC 24 10520 BCL11A-8780 - GAGGAGCUGACGGAGAGC 18 10521 BCL11A-8781 - GGAGGAGCUGACGGAGAGC 19 10522 BCL11A-8782 - AGGAGGAGCUGACGGAGAGC 20 10523 BCL11A-8783 - GAGGAGGAGCUGACGGAGAGC 21 10524 BCL11A-8784 - GGAGGAGGAGCUGACGGAGAGC 22 10525 BCL11A-8785 - AGGAGGAGGAGCUGACGGAGAGC 23 10526 BCL11A-8786 - GAGGAGGAGGAGCUGACGGAGAGC 24 10527 BCL11A-8787 - UACGGCUUCGGGCUGAGC 18 10528 BCL11A-8788 - CUACGGCUUCGGGCUGAGC 19 10529 BCL11A-8789 - ACUACGGCUUCGGGCUGAGC 20 10530 BCL11A-8790 - GACUACGGCUUCGGGCUGAGC 21 10531 BCL11A-8791 - GGACUACGGCUUCGGGCUGAGC 22 10532 BCL11A-8792 - UGGACUACGGCUUCGGGCUGAGC 23 10533 BCL11A-8793 - GUGGACUACGGCUUCGGGCUGAGC 24 10534 BCL11A-8794 - UGCGCUUCUCCACACCGC 18 10535 BCL11A-8795 - UUGCGCUUCUCCACACCGC 19 10536 BCL11A-8796 - UUUGCGCUUCUCCACACCGC 20 10537 BCL11A-8797 - GUUUGCGCUUCUCCACACCGC 21 10538 BCL11A-8798 - AGUUUGCGCUUCUCCACACCGC 22 10539 BCL11A-8799 - GAGUUUGCGCUUCUCCACACCGC 23 10540 BCL11A-8800 - GGAGUUUGCGCUUCUCCACACCGC 24 10541 BCL11A-8801 - CCCCACCGCAUAGAGCGC 18 10542 BCL11A-8802 - CCCCCACCGCAUAGAGCGC 19 10543 BCL11A-8803 - ACCCCCACCGCAUAGAGCGC 20 10544 BCL11A-8804 - GACCCCCACCGCAUAGAGCGC 21 10545 BCL11A-8805 - GGACCCCCACCGCAUAGAGCGC 22 10546 BCL11A-8806 - UGGACCCCCACCGCAUAGAGCGC 23 10547 BCL11A-8807 - UUGGACCCCCACCGCAUAGAGCGC 24 10548 BCL11A-8808 - AUCUCGGGGCGCAGCGGC 18 10549 BCL11A-8809 - GAUCUCGGGGCGCAGCGGC 19 10550 BCL11A-8810 - GGAUCUCGGGGCGCAGCGGC 20 10551 BCL11A-8811 - GGGAUCUCGGGGCGCAGCGGC 21 10552 BCL11A-8812 - AGGGAUCUCGGGGCGCAGCGGC 22 10553 BCL11A-8813 - GAGGGAUCUCGGGGCGCAGCGGC 23 10554 BCL11A-8814 - GGAGGGAUCUCGGGGCGCAGCGGC 24 10555 BCL11A-8815 - CGGCGCAGCCACACGGGC 18 10556 BCL11A-8816 - CCGGCGCAGCCACACGGGC 19 10557 BCL11A-3804 - ACCGGCGCAGCCACACGGGC 20 10558 BCL11A-8817 - CACCGGCGCAGCCACACGGGC 21 10559 BCL11A-8818 - GCACCGGCGCAGCCACACGGGC 22 10560 BCL11A-8819 - UGCACCGGCGCAGCCACACGGGC 23 10561 BCL11A-8820 - GUGCACCGGCGCAGCCACACGGGC 24 10562 BCL11A-8821 - CAUAUUAGUGGUCCGGGC 18 10563 BCL11A-8822 - CCAUAUUAGUGGUCCGGGC 19 10564 BCL11A-8823 - CCCAUAUUAGUGGUCCGGGC 20 10565 BCL11A-8824 - CCCCAUAUUAGUGGUCCGGGC 21 10566 BCL11A-8825 - GCCCCAUAUUAGUGGUCCGGGC 22 10567 BCL11A-8826 - CGCCCCAUAUUAGUGGUCCGGGC 23 10568 BCL11A-8827 - ACGCCCCAUAUUAGUGGUCCGGGC 24 10569 BCL11A-8828 - UUCCACCAGGUCCUGGGC 18 10570 BCL11A-8829 - CUUCCACCAGGUCCUGGGC 19 10571 BCL11A-8830 - CCUUCCACCAGGUCCUGGGC 20 10572 BCL11A-8831 - GCCUUCCACCAGGUCCUGGGC 21 10573 BCL11A-8832 - GGCCUUCCACCAGGUCCUGGGC 22 10574 BCL11A-8833 - AGGCCUUCCACCAGGUCCUGGGC 23 10575 BCL11A-8834 - GAGGCCUUCCACCAGGUCCUGGGC 24 10576 BCL11A-8835 - CGGGGCGCGGUCGUGGGC 18 10577 BCL11A-8836 - GCGGGGCGCGGUCGUGGGC 19 10578 BCL11A-8837 - CGCGGGGCGCGGUCGUGGGC 20 10579 BCL11A-8838 - UCGCGGGGCGCGGUCGUGGGC 21 10580 BCL11A-8839 - CUCGCGGGGCGCGGUCGUGGGC 22 10581 BCL11A-8840 - GCUCGCGGGGCGCGGUCGUGGGC 23 10582 BCL11A-8841 - AGCUCGCGGGGCGCGGUCGUGGGC 24 10583 BCL11A-8842 - GAGACUUAGAGAGCUGGC 18 10584 BCL11A-8843 - GGAGACUUAGAGAGCUGGC 19 10585 BCL11A-6037 - AGGAGACUUAGAGAGCUGGC 20 10586 BCL11A-8844 - UAGGAGACUUAGAGAGCUGGC 21 10587 BCL11A-8845 - CUAGGAGACUUAGAGAGCUGGC 22 10588 BCL11A-8846 - UCUAGGAGACUUAGAGAGCUGGC 23 10589 BCL11A-8847 - CUCUAGGAGACUUAGAGAGCUGGC 24 10590 BCL11A-8848 - GAGCUGGACGGAGGGAUC 18 10591 BCL11A-8849 - GGAGCUGGACGGAGGGAUC 19 10592 BCL11A-8850 - GGGAGCUGGACGGAGGGAUC 20 10593 BCL11A-8851 - GGGGAGCUGGACGGAGGGAUC 21 10594 BCL11A-8852 - CGGGGAGCUGGACGGAGGGAUC 22 10595 BCL11A-8853 - CCGGGGAGCUGGACGGAGGGAUC 23 10596 BCL11A-8854 - CCCGGGGAGCUGGACGGAGGGAUC 24 10597 BCL11A-8855 - AACGACCCCAACCUGAUC 18 10598 BCL11A-8856 - GAACGACCCCAACCUGAUC 19 10599 BCL11A-8857 - AGAACGACCCCAACCUGAUC 20 10600 BCL11A-8858 - GAGAACGACCCCAACCUGAUC 21 10601 BCL11A-8859 - CGAGAACGACCCCAACCUGAUC 22 10602 BCL11A-8860 - GCGAGAACGACCCCAACCUGAUC 23 10603 BCL11A-8861 - AGCGAGAACGACCCCAACCUGAUC 24 10604 BCL11A-8862 - AAUACCAGGAUCAGUAUC 18 10605 BCL11A-8863 - GAAUACCAGGAUCAGUAUC 19 10606 BCL11A-8864 - AGAAUACCAGGAUCAGUAUC 20 10607 BCL11A-8865 - AAGAAUACCAGGAUCAGUAUC 21 10608 BCL11A-8866 - UAAGAAUACCAGGAUCAGUAUC 22 10609 BCL11A-8867 - CUAAGAAUACCAGGAUCAGUAUC 23 10610 BCL11A-8868 - GCUAAGAAUACCAGGAUCAGUAUC 24 10611 BCL11A-8869 - CCCGGGCGAGUCGGCCUC 18 10612 BCL11A-8870 - CCCCGGGCGAGUCGGCCUC 19 10613 BCL11A-6047 - UCCCCGGGCGAGUCGGCCUC 20 10614 BCL11A-8871 - CUCCCCGGGCGAGUCGGCCUC 21 10615 BCL11A-8872 - GCUCCCCGGGCGAGUCGGCCUC 22 10616 BCL11A-8873 - UGCUCCCCGGGCGAGUCGGCCUC 23 10617 BCL11A-8874 - CUGCUCCCCGGGCGAGUCGGCCUC 24 10618 BCL11A-8875 - UCUAAGCGCAUCAAGCUC 18 10619 BCL11A-8876 - CUCUAAGCGCAUCAAGCUC 19 10620 BCL11A-8877 - UCUCUAAGCGCAUCAAGCUC 20 10621 BCL11A-8878 - UUCUCUAAGCGCAUCAAGCUC 21 10622 BCL11A-8879 - CUUCUCUAAGCGCAUCAAGCUC 22 10623 BCL11A-8880 - CCUUCUCUAAGCGCAUCAAGCUC 23 10624 BCL11A-8881 - CCCUUCUCUAAGCGCAUCAAGCUC 24 10625 BCL11A-8882 - GUUUUCGGAUGGAAGCUC 18 10626 BCL11A-8883 - AGUUUUCGGAUGGAAGCUC 19 10627 BCL11A-8884 - CAGUUUUCGGAUGGAAGCUC 20 10628 BCL11A-8885 - GCAGUUUUCGGAUGGAAGCUC 21 10629 BCL11A-8886 - GGCAGUUUUCGGAUGGAAGCUC 22 10630 BCL11A-8887 - UGGCAGUUUUCGGAUGGAAGCUC 23 10631 BCL11A-8888 - GUGGCAGUUUUCGGAUGGAAGCUC 24 10632 BCL11A-8889 - CCACCACGAGAACAGCUC 18 10633 BCL11A-8890 - GCCACCACGAGAACAGCUC 19 10634 BCL11A-8891 - CGCCACCACGAGAACAGCUC 20 10635 BCL11A-8892 - GCGCCACCACGAGAACAGCUC 21 10636 BCL11A-8893 - CGCGCCACCACGAGAACAGCUC 22 10637 BCL11A-8894 - GCGCGCCACCACGAGAACAGCUC 23 10638 BCL11A-8895 - GGCGCGCCACCACGAGAACAGCUC 24 10639 BCL11A-8896 - UCCCGCCAUGGAUUUCUC 18 10640 BCL11A-8897 - CUCCCGCCAUGGAUUUCUC 19 10641 BCL11A-8898 - CCUCCCGCCAUGGAUUUCUC 20 10642 BCL11A-8899 - GCCUCCCGCCAUGGAUUUCUC 21 10643 BCL11A-8900 - AGCCUCCCGCCAUGGAUUUCUC 22 10644 BCL11A-8901 - GAGCCUCCCGCCAUGGAUUUCUC 23 10645 BCL11A-8902 - GGAGCCUCCCGCCAUGGAUUUCUC 24 10646 BCL11A-8903 - GAGGCCUUCCACCAGGUC 18 10647 BCL11A-8904 - CGAGGCCUUCCACCAGGUC 19 10648 BCL11A-8905 - GCGAGGCCUUCCACCAGGUC 20 10649 BCL11A-8906 - AGCGAGGCCUUCCACCAGGUC 21 10650 BCL11A-8907 - CAGCGAGGCCUUCCACCAGGUC 22 10651 BCL11A-8908 - UCAGCGAGGCCUUCCACCAGGUC 23 10652 BCL11A-8909 - UUCAGCGAGGCCUUCCACCAGGUC 24 10653 BCL11A-8910 - AGCUCGCGGGGCGCGGUC 18 10654 BCL11A-8911 - CAGCUCGCGGGGCGCGGUC 19 10655 BCL11A-8912 - ACAGCUCGCGGGGCGCGGUC 20 10656 BCL11A-8913 - AACAGCUCGCGGGGCGCGGUC 21 10657 BCL11A-8914 - GAACAGCUCGCGGGGCGCGGUC 22 10658 BCL11A-8915 - AGAACAGCUCGCGGGGCGCGGUC 23 10659 BCL11A-8916 - GAGAACAGCUCGCGGGGCGCGGUC 24 10660 BCL11A-8917 - UACUGUGGGAAAGUCUUC 18 10661 BCL11A-8918 - GUACUGUGGGAAAGUCUUC 19 10662 BCL11A-8919 - AGUACUGUGGGAAAGUCUUC 20 10663 BCL11A-8920 - GAGUACUGUGGGAAAGUCUUC 21 10664 BCL11A-8921 - UGAGUACUGUGGGAAAGUCUUC 22 10665 BCL11A-8922 - GUGAGUACUGUGGGAAAGUCUUC 23 10666 BCL11A-8923 - UGUGAGUACUGUGGGAAAGUCUUC 24 10667 BCL11A-8924 - UCCGUGGUGGCCAAGUUC 18 10668 BCL11A-8925 - GUCCGUGGUGGCCAAGUUC 19 10669 BCL11A-8926 - AGUCCGUGGUGGCCAAGUUC 20 10670 BCL11A-8927 - AAGUCCGUGGUGGCCAAGUUC 21 10671 BCL11A-8928 - CAAGUCCGUGGUGGCCAAGUUC 22 10672 BCL11A-8929 - UCAAGUCCGUGGUGGCCAAGUUC 23 10673 BCL11A-8930 - CUCAAGUCCGUGGUGGCCAAGUUC 24 10674 BCL11A-6826 - AUUAUUUUGCAGGUAAAG 18 10675 BCL11A-6827 - UAUUAUUUUGCAGGUAAAG 19 10676 BCL11A-6828 - GUAUUAUUUUGCAGGUAAAG 20 10677 BCL11A-8931 - UGCACCCAGGCCAGCAAG 18 10678 BCL11A-8932 - GUGCACCCAGGCCAGCAAG 19 10679 BCL11A-8933 - CGUGCACCCAGGCCAGCAAG 20 10680 BCL11A-8934 - GCGUGCACCCAGGCCAGCAAG 21 10681 BCL11A-8935 - CGCGUGCACCCAGGCCAGCAAG 22 10682 BCL11A-8936 - ACGCGUGCACCCAGGCCAGCAAG 23 10683 BCL11A-8937 - CACGCGUGCACCCAGGCCAGCAAG 24 10684 BCL11A-8938 - ACGAGGAAGAGGAAGAAG 18 10685 BCL11A-8939 - GACGAGGAAGAGGAAGAAG 19 10686 BCL11A-3449 - CGACGAGGAAGAGGAAGAAG 20 10687 BCL11A-8940 - ACGACGAGGAAGAGGAAGAAG 21 10688 BCL11A-8941 - GACGACGAGGAAGAGGAAGAAG 22 10689 BCL11A-8942 - GGACGACGAGGAAGAGGAAGAAG 23 10690 BCL11A-8943 - AGGACGACGAGGAAGAGGAAGAAG 24 10691 BCL11A-8944 - ACGACGAGGAAGAGGAAG 18 10692 BCL11A-8945 - GACGACGAGGAAGAGGAAG 19 10693 BCL11A-3959 - GGACGACGAGGAAGAGGAAG 20 10694 BCL11A-8946 - AGGACGACGAGGAAGAGGAAG 21 10695 BCL11A-8947 - GAGGACGACGAGGAAGAGGAAG 22 10696 BCL11A-8948 - GGAGGACGACGAGGAAGAGGAAG 23 10697 BCL11A-8949 - AGGAGGACGACGAGGAAGAGGAAG 24 10698 BCL11A-8950 - AGGAGGACGACGAGGAAG 18 10699 BCL11A-8951 - GAGGAGGACGACGAGGAAG 19 10700 BCL11A-3448 - AGAGGAGGACGACGAGGAAG 20 10701 BCL11A-8952 - AAGAGGAGGACGACGAGGAAG 21 10702 BCL11A-8953 - GAAGAGGAGGACGACGAGGAAG 22 10703 BCL11A-8954 - GGAAGAGGAGGACGACGAGGAAG 23 10704 BCL11A-8955 - AGGAAGAGGAGGACGACGAGGAAG 24 10705 BCL11A-8956 - AGGAAGAAGAGGAGGAAG 18 10706 BCL11A-8957 - GAGGAAGAAGAGGAGGAAG 19 10707 BCL11A-3453 - AGAGGAAGAAGAGGAGGAAG 20 10708 BCL11A-8958 - AAGAGGAAGAAGAGGAGGAAG 21 10709 BCL11A-8959 - GAAGAGGAAGAAGAGGAGGAAG 22 10710 BCL11A-8960 - GGAAGAGGAAGAAGAGGAGGAAG 23 10711 BCL11A-8961 - AGGAAGAGGAAGAAGAGGAGGAAG 24 10712 BCL11A-8962 - ACGGGGACGAGGAGGAAG 18 10713 BCL11A-8963 - AACGGGGACGAGGAGGAAG 19 10714 BCL11A-3441 - GAACGGGGACGAGGAGGAAG 20 10715 BCL11A-8964 - AGAACGGGGACGAGGAGGAAG 21 10716 BCL11A-8965 - GAGAACGGGGACGAGGAGGAAG 22 10717 BCL11A-8966 - GGAGAACGGGGACGAGGAGGAAG 23 10718 BCL11A-8967 - CGGAGAACGGGGACGAGGAGGAAG 24 10719 BCL11A-8968 - GCGCAGCGGCACGGGAAG 18 10720 BCL11A-8969 - GGCGCAGCGGCACGGGAAG 19 10721 BCL11A-3376 - GGGCGCAGCGGCACGGGAAG 20 10722 BCL11A-8970 - GGGGCGCAGCGGCACGGGAAG 21 10723 BCL11A-8971 - CGGGGCGCAGCGGCACGGGAAG 22 10724 BCL11A-8972 - UCGGGGCGCAGCGGCACGGGAAG 23 10725 BCL11A-8973 - CUCGGGGCGCAGCGGCACGGGAAG 24 10726 BCL11A-8974 - AGGCUUCCGGCCUGGCAG 18 10727 BCL11A-8975 - GAGGCUUCCGGCCUGGCAG 19 10728 BCL11A-8976 - AGAGGCUUCCGGCCUGGCAG 20 10729 BCL11A-8977 - GAGAGGCUUCCGGCCUGGCAG 21 10730 BCL11A-8978 - AGAGAGGCUUCCGGCCUGGCAG 22 10731 BCL11A-8979 - GAGAGAGGCUUCCGGCCUGGCAG 23 10732 BCL11A-8980 - CGAGAGAGGCUUCCGGCCUGGCAG 24 10733 BCL11A-8981 - GAGGAAGAGGAAGAAGAG 18 10734 BCL11A-8982 - CGAGGAAGAGGAAGAAGAG 19 10735 BCL11A-3948 - ACGAGGAAGAGGAAGAAGAG 20 10736 BCL11A-8983 - GACGAGGAAGAGGAAGAAGAG 21 10737 BCL11A-8984 - CGACGAGGAAGAGGAAGAAGAG 22 10738 BCL11A-8985 - ACGACGAGGAAGAGGAAGAAGAG 23 10739 BCL11A-8986 - GACGACGAGGAAGAGGAAGAAGAG 24 10740 BCL11A-8987 - GAAGAAGAGGAGGAAGAG 18 10741 BCL11A-8988 - GGAAGAAGAGGAGGAAGAG 19 10742 BCL11A-3961 - AGGAAGAAGAGGAGGAAGAG 20 10743 BCL11A-8989 - GAGGAAGAAGAGGAGGAAGAG 21 10744 BCL11A-8990 - AGAGGAAGAAGAGGAGGAAGAG 22 10745 BCL11A-8991 - AAGAGGAAGAAGAGGAGGAAGAG 23 10746 BCL11A-8992 - GAAGAGGAAGAAGAGGAGGAAGAG 24 10747 BCL11A-8993 - GGGGACGAGGAGGAAGAG 18 10748 BCL11A-8994 - CGGGGACGAGGAGGAAGAG 19 10749 BCL11A-3945 - ACGGGGACGAGGAGGAAGAG 20 10750 BCL11A-8995 - AACGGGGACGAGGAGGAAGAG 21 10751 BCL11A-8996 - GAACGGGGACGAGGAGGAAGAG 22 10752 BCL11A-8997 - AGAACGGGGACGAGGAGGAAGAG 23 10753 BCL11A-8998 - GAGAACGGGGACGAGGAGGAAGAG 24 10754 BCL11A-8999 - CCGGAGAACGGGGACGAG 18 10755 BCL11A-9000 - CCCGGAGAACGGGGACGAG 19 10756 BCL11A-9001 - UCCCGGAGAACGGGGACGAG 20 10757 BCL11A-9002 - AUCCCGGAGAACGGGGACGAG 21 10758 BCL11A-9003 - GAUCCCGGAGAACGGGGACGAG 22 10759 BCL11A-9004 - UGAUCCCGGAGAACGGGGACGAG 23 10760 BCL11A-9005 - CUGAUCCCGGAGAACGGGGACGAG 24 10761 BCL11A-9006 - GACUCGGUGGCCGGCGAG 18 10762 BCL11A-9007 - AGACUCGGUGGCCGGCGAG 19 10763 BCL11A-9008 - AAGACUCGGUGGCCGGCGAG 20 10764 BCL11A-9009 - GAAGACUCGGUGGCCGGCGAG 21 10765 BCL11A-9010 - CGAAGACUCGGUGGCCGGCGAG 22 10766 BCL11A-9011 - ACGAAGACUCGGUGGCCGGCGAG 23 10767 BCL11A-9012 - GACGAAGACUCGGUGGCCGGCGAG 24 10768 BCL11A-9013 - AAGCGCAUCAAGCUCGAG 18 10769 BCL11A-9014 - UAAGCGCAUCAAGCUCGAG 19 10770 BCL11A-9015 - CUAAGCGCAUCAAGCUCGAG 20 10771 BCL11A-9016 - UCUAAGCGCAUCAAGCUCGAG 21 10772 BCL11A-9017 - CUCUAAGCGCAUCAAGCUCGAG 22 10773 BCL11A-9018 - UCUCUAAGCGCAUCAAGCUCGAG 23 10774 BCL11A-9019 - UUCUCUAAGCGCAUCAAGCUCGAG 24 10775 BCL11A-9020 - GAAGAGGAGGAAGAGGAG 18 10776 BCL11A-9021 - AGAAGAGGAGGAAGAGGAG 19 10777 BCL11A-3964 - AAGAAGAGGAGGAAGAGGAG 20 10778 BCL11A-9022 - GAAGAAGAGGAGGAAGAGGAG 21 10779 BCL11A-9023 - GGAAGAAGAGGAGGAAGAGGAG 22 10780 BCL11A-9024 - AGGAAGAAGAGGAGGAAGAGGAG 23 10781 BCL11A-9025 - GAGGAAGAAGAGGAGGAAGAGGAG 24 10782 BCL11A-9026 - GAGGAGGAAGAGGAGGAG 18 10783 BCL11A-9027 - AGAGGAGGAAGAGGAGGAG 19 10784 BCL11A-3965 - AAGAGGAGGAAGAGGAGGAG 20 10785 BCL11A-9028 - GAAGAGGAGGAAGAGGAGGAG 21 10786 BCL11A-9029 - AGAAGAGGAGGAAGAGGAGGAG 22 10787 BCL11A-9030 - AAGAAGAGGAGGAAGAGGAGGAG 23 10788 BCL11A-9031 - GAAGAAGAGGAGGAAGAGGAGGAG 24 10789 BCL11A-9032 - UCCACACCGCCCGGGGAG 18 10790 BCL11A-9033 - CUCCACACCGCCCGGGGAG 19 10791 BCL11A-9034 - UCUCCACACCGCCCGGGGAG 20 10792 BCL11A-9035 - UUCUCCACACCGCCCGGGGAG 21 10793 BCL11A-9036 - CUUCUCCACACCGCCCGGGGAG 22 10794 BCL11A-9037 - GCUUCUCCACACCGCCCGGGGAG 23 10795 BCL11A-9038 - CGCUUCUCCACACCGCCCGGGGAG 24 10796 BCL11A-9039 - GCCGCGAUGCCCAACACG 18 10797 BCL11A-9040 - GGCCGCGAUGCCCAACACG 19 10798 BCL11A-9041 - CGGCCGCGAUGCCCAACACG 20 10799 BCL11A-9042 - CCGGCCGCGAUGCCCAACACG 21 10800 BCL11A-9043 - CCCGGCCGCGAUGCCCAACACG 22 10801 BCL11A-9044 - CCCCGGCCGCGAUGCCCAACACG 23 10802 BCL11A-9045 - CCCCCGGCCGCGAUGCCCAACACG 24 10803 BCL11A-9046 - AGGAAGAGGAGGACGACG 18 10804 BCL11A-9047 - GAGGAAGAGGAGGACGACG 19 10805 BCL11A-3450 - GGAGGAAGAGGAGGACGACG 20 10806 BCL11A-9048 - AGGAGGAAGAGGAGGACGACG 21 10807 BCL11A-9049 - GAGGAGGAAGAGGAGGACGACG 22 10808 BCL11A-9050 - CGAGGAGGAAGAGGAGGACGACG 23 10809 BCL11A-9051 - ACGAGGAGGAAGAGGAGGACGACG 24 10810 BCL11A-9052 - AGGAGGAAGAGGAGGACG 18 10811 BCL11A-9053 - GAGGAGGAAGAGGAGGACG 19 10812 BCL11A-3953 - CGAGGAGGAAGAGGAGGACG 20 10813 BCL11A-9054 - ACGAGGAGGAAGAGGAGGACG 21 10814 BCL11A-9055 - GACGAGGAGGAAGAGGAGGACG 22 10815 BCL11A-9056 - GGACGAGGAGGAAGAGGAGGACG 23 10816 BCL11A-9057 - GGGACGAGGAGGAAGAGGAGGACG 24 10817 BCL11A-9058 - UCCCGGAGAACGGGGACG 18 10818 BCL11A-9059 - AUCCCGGAGAACGGGGACG 19 10819 BCL11A-6081 - GAUCCCGGAGAACGGGGACG 20 10820 BCL11A-9060 - UGAUCCCGGAGAACGGGGACG 21 10821 BCL11A-9061 - CUGAUCCCGGAGAACGGGGACG 22 10822 BCL11A-9062 - CCUGAUCCCGGAGAACGGGGACG 23 10823 BCL11A-9063 - ACCUGAUCCCGGAGAACGGGGACG 24 10824 BCL11A-9064 - CGCCCGGGGAGCUGGACG 18 10825 BCL11A-9065 - CCGCCCGGGGAGCUGGACG 19 10826 BCL11A-9066 - ACCGCCCGGGGAGCUGGACG 20 10827 BCL11A-9067 - CACCGCCCGGGGAGCUGGACG 21 10828 BCL11A-9068 - ACACCGCCCGGGGAGCUGGACG 22 10829 BCL11A-9069 - CACACCGCCCGGGGAGCUGGACG 23 10830 BCL11A-9070 - CCACACCGCCCGGGGAGCUGGACG 24 10831 BCL11A-9071 - GAGGAGGAGGAGCUGACG 18 10832 BCL11A-9072 - GGAGGAGGAGGAGCUGACG 19 10833 BCL11A-9073 - AGGAGGAGGAGGAGCUGACG 20 10834 BCL11A-9074 - GAGGAGGAGGAGGAGCUGACG 21 10835 BCL11A-9075 - AGAGGAGGAGGAGGAGCUGACG 22 10836 BCL11A-9076 - AAGAGGAGGAGGAGGAGCUGACG 23 10837 BCL11A-9077 - GAAGAGGAGGAGGAGGAGCUGACG 24 10838 BCL11A-9078 - GCUUCUCCACACCGCCCG 18 10839 BCL11A-9079 - CGCUUCUCCACACCGCCCG 19 10840 BCL11A-6087 - GCGCUUCUCCACACCGCCCG 20 10841 BCL11A-9080 - UGCGCUUCUCCACACCGCCCG 21 10842 BCL11A-9081 - UUGCGCUUCUCCACACCGCCCG 22 10843 BCL11A-9082 - UUUGCGCUUCUCCACACCGCCCG 23 10844 BCL11A-9083 - GUUUGCGCUUCUCCACACCGCCCG 24 10845 BCL11A-9084 - GACCCCAACCUGAUCCCG 18 10846 BCL11A-9085 - CGACCCCAACCUGAUCCCG 19 10847 BCL11A-9086 - ACGACCCCAACCUGAUCCCG 20 10848 BCL11A-9087 - AACGACCCCAACCUGAUCCCG 21 10849 BCL11A-9088 - GAACGACCCCAACCUGAUCCCG 22 10850 BCL11A-9089 - AGAACGACCCCAACCUGAUCCCG 23 10851 BCL11A-9090 - GAGAACGACCCCAACCUGAUCCCG 24 10852 BCL11A-9091 - CGGUCGUGGGCGUGGGCG 18 10853 BCL11A-9092 - GCGGUCGUGGGCGUGGGCG 19 10854 BCL11A-9093 - CGCGGUCGUGGGCGUGGGCG 20 10855 BCL11A-9094 - GCGCGGUCGUGGGCGUGGGCG 21 10856 BCL11A-9095 - GGCGCGGUCGUGGGCGUGGGCG 22 10857 BCL11A-9096 - GGGCGCGGUCGUGGGCGUGGGCG 23 10858 BCL11A-9097 - GGGGCGCGGUCGUGGGCGUGGGCG 24 10859 BCL11A-9098 - GCCACAGGGACACUUGCG 18 10860 BCL11A-9099 - GGCCACAGGGACACUUGCG 19 10861 BCL11A-9100 - GGGCCACAGGGACACUUGCG 20 10862 BCL11A-9101 - AGGGCCACAGGGACACUUGCG 21 10863 BCL11A-9102 - GAGGGCCACAGGGACACUUGCG 22 10864 BCL11A-9103 - CGAGGGCCACAGGGACACUUGCG 23 10865 BCL11A-9104 - CCGAGGGCCACAGGGACACUUGCG 24 10866 BCL11A-9105 - CCGGGCGAGUCGGCCUCG 18 10867 BCL11A-9106 - CCCGGGCGAGUCGGCCUCG 19 10868 BCL11A-6106 - CCCCGGGCGAGUCGGCCUCG 20 10869 BCL11A-9107 - UCCCCGGGCGAGUCGGCCUCG 21 10870 BCL11A-9108 - CUCCCCGGGCGAGUCGGCCUCG 22 10871 BCL11A-9109 - GCUCCCCGGGCGAGUCGGCCUCG 23 10872 BCL11A-9110 - UGCUCCCCGGGCGAGUCGGCCUCG 24 10873 BCL11A-9111 - UCGUCGGAGCACUCCUCG 18 10874 BCL11A-9112 - CUCGUCGGAGCACUCCUCG 19 10875 BCL11A-9113 - CCUCGUCGGAGCACUCCUCG 20 10876 BCL11A-9114 - UCCUCGUCGGAGCACUCCUCG 21 10877 BCL11A-9115 - CUCCUCGUCGGAGCACUCCUCG 22 10878 BCL11A-9116 - CCUCCUCGUCGGAGCACUCCUCG 23 10879 BCL11A-9117 - GCCUCCUCGUCGGAGCACUCCUCG 24 10880 BCL11A-9118 - UCGCCUUUUGCCUCCUCG 18 10881 BCL11A-9119 - AUCGCCUUUUGCCUCCUCG 19 10882 BCL11A-9120 - AAUCGCCUUUUGCCUCCUCG 20 10883 BCL11A-9121 - CAAUCGCCUUUUGCCUCCUCG 21 10884 BCL11A-9122 - ACAAUCGCCUUUUGCCUCCUCG 22 10885 BCL11A-9123 - GACAAUCGCCUUUUGCCUCCUCG 23 10886 BCL11A-9124 - AGACAAUCGCCUUUUGCCUCCUCG 24 10887 BCL11A-9125 - CACCACGAGAACAGCUCG 18 10888 BCL11A-9126 - CCACCACGAGAACAGCUCG 19 10889 BCL11A-6107 - GCCACCACGAGAACAGCUCG 20 10890 BCL11A-9127 - CGCCACCACGAGAACAGCUCG 21 10891 BCL11A-9128 - GCGCCACCACGAGAACAGCUCG 22 10892 BCL11A-9129 - CGCGCCACCACGAGAACAGCUCG 23 10893 BCL11A-9130 - GCGCGCCACCACGAGAACAGCUCG 24 10894 BCL11A-9131 - CUGGGCAGCCCCAGCUCG 18 10895 BCL11A-9132 - GCUGGGCAGCCCCAGCUCG 19 10896 BCL11A-9133 - UGCUGGGCAGCCCCAGCUCG 20 10897 BCL11A-9134 - CUGCUGGGCAGCCCCAGCUCG 21 10898 BCL11A-9135 - GCUGCUGGGCAGCCCCAGCUCG 22 10899 BCL11A-9136 - UGCUGCUGGGCAGCCCCAGCUCG 23 10900 BCL11A-9137 - CUGCUGCUGGGCAGCCCCAGCUCG 24 10901 BCL11A-9138 - AGGAAGAGGAAGAAGAGG 18 10902 BCL11A-9139 - GAGGAAGAGGAAGAAGAGG 19 10903 BCL11A-3451 - CGAGGAAGAGGAAGAAGAGG 20 10904 BCL11A-9140 - ACGAGGAAGAGGAAGAAGAGG 21 10905 BCL11A-9141 - GACGAGGAAGAGGAAGAAGAGG 22 10906 BCL11A-9142 - CGACGAGGAAGAGGAAGAAGAGG 23 10907 BCL11A-9143 - ACGACGAGGAAGAGGAAGAAGAGG 24 10908 BCL11A-9144 - AGGACGACGAGGAAGAGG 18 10909 BCL11A-9145 - GAGGACGACGAGGAAGAGG 19 10910 BCL11A-3957 - GGAGGACGACGAGGAAGAGG 20 10911 BCL11A-9146 - AGGAGGACGACGAGGAAGAGG 21 10912 BCL11A-9147 - GAGGAGGACGACGAGGAAGAGG 22 10913 BCL11A-9148 - AGAGGAGGACGACGAGGAAGAGG 23 10914 BCL11A-9149 - AAGAGGAGGACGACGAGGAAGAGG 24 10915 BCL11A-9150 - AAGAAGAGGAGGAAGAGG 18 10916 BCL11A-9151 - GAAGAAGAGGAGGAAGAGG 19 10917 BCL11A-3452 - GGAAGAAGAGGAGGAAGAGG 20 10918 BCL11A-9152 - AGGAAGAAGAGGAGGAAGAGG 21 10919 BCL11A-9153 - GAGGAAGAAGAGGAGGAAGAGG 22 10920 BCL11A-9154 - AGAGGAAGAAGAGGAGGAAGAGG 23 10921 BCL11A-9155 - AAGAGGAAGAAGAGGAGGAAGAGG 24 10922 BCL11A-9156 - CUGACGGAGAGCGAGAGG 18 10923 BCL11A-9157 - GCUGACGGAGAGCGAGAGG 19 10924 BCL11A-9158 - AGCUGACGGAGAGCGAGAGG 20 10925 BCL11A-9159 - GAGCUGACGGAGAGCGAGAGG 21 10926 BCL11A-9160 - GGAGCUGACGGAGAGCGAGAGG 22 10927 BCL11A-9161 - AGGAGCUGACGGAGAGCGAGAGG 23 10928 BCL11A-9162 - GAGGAGCUGACGGAGAGCGAGAGG 24 10929 BCL11A-9163 - AAGAGGAGGACGACGAGG 18 10930 BCL11A-9164 - GAAGAGGAGGACGACGAGG 19 10931 BCL11A-3960 - GGAAGAGGAGGACGACGAGG 20 10932 BCL11A-9165 - AGGAAGAGGAGGACGACGAGG 21 10933 BCL11A-9166 - GAGGAAGAGGAGGACGACGAGG 22 10934 BCL11A-9167 - GGAGGAAGAGGAGGACGACGAGG 23 10935 BCL11A-9168 - AGGAGGAAGAGGAGGACGACGAGG 24 10936 BCL11A-9169 - CGGAGAACGGGGACGAGG 18 10937 BCL11A-9170 - CCGGAGAACGGGGACGAGG 19 10938 BCL11A-3330 - CCCGGAGAACGGGGACGAGG 20 10939 BCL11A-9171 - UCCCGGAGAACGGGGACGAGG 21 10940 BCL11A-9172 - AUCCCGGAGAACGGGGACGAGG 22 10941 BCL11A-9173 - GAUCCCGGAGAACGGGGACGAGG 23 10942 BCL11A-9174 - UGAUCCCGGAGAACGGGGACGAGG 24 10943 BCL11A-9175 - GCGGCCACCUGGCCGAGG 18 10944 BCL11A-9176 - CGCGGCCACCUGGCCGAGG 19 10945 BCL11A-9177 - GCGCGGCCACCUGGCCGAGG 20 10946 BCL11A-9178 - AGCGCGGCCACCUGGCCGAGG 21 10947 BCL11A-9179 - AAGCGCGGCCACCUGGCCGAGG 22 10948 BCL11A-9180 - UAAGCGCGGCCACCUGGCCGAGG 23 10949 BCL11A-9181 - AUAAGCGCGGCCACCUGGCCGAGG 24 10950 BCL11A-9182 - AAGAGGAAGAAGAGGAGG 18 10951 BCL11A-9183 - GAAGAGGAAGAAGAGGAGG 19 10952 BCL11A-3963 - GGAAGAGGAAGAAGAGGAGG 20 10953 BCL11A-9184 - AGGAAGAGGAAGAAGAGGAGG 21 10954 BCL11A-9185 - GAGGAAGAGGAAGAAGAGGAGG 22 10955 BCL11A-9186 - CGAGGAAGAGGAAGAAGAGGAGG 23 10956 BCL11A-9187 - ACGAGGAAGAGGAAGAAGAGGAGG 24 10957 BCL11A-9188 - AAGAGGAGGAAGAGGAGG 18 10958 BCL11A-9189 - GAAGAGGAGGAAGAGGAGG 19 10959 BCL11A-3454 - AGAAGAGGAGGAAGAGGAGG 20 10960 BCL11A-9190 - AAGAAGAGGAGGAAGAGGAGG 21 10961 BCL11A-9191 - GAAGAAGAGGAGGAAGAGGAGG 22 10962 BCL11A-9192 - GGAAGAAGAGGAGGAAGAGGAGG 23 10963 BCL11A-9193 - AGGAAGAAGAGGAGGAAGAGGAGG 24 10964 BCL11A-9194 - AGAACGGGGACGAGGAGG 18 10965 BCL11A-9195 - GAGAACGGGGACGAGGAGG 19 10966 BCL11A-3918 - GGAGAACGGGGACGAGGAGG 20 10967 BCL11A-9196 - CGGAGAACGGGGACGAGGAGG 21 10968 BCL11A-9197 - CCGGAGAACGGGGACGAGGAGG 22 10969 BCL11A-9198 - CCCGGAGAACGGGGACGAGGAGG 23 10970 BCL11A-9199 - UCCCGGAGAACGGGGACGAGGAGG 24 10971 BCL11A-9200 - AGGAGGAAGAGGAGGAGG 18 10972 BCL11A-9201 - GAGGAGGAAGAGGAGGAGG 19 10973 BCL11A-3455 - AGAGGAGGAAGAGGAGGAGG 20 10974 BCL11A-9202 - AAGAGGAGGAAGAGGAGGAGG 21 10975 BCL11A-9203 - GAAGAGGAGGAAGAGGAGGAGG 22 10976 BCL11A-9204 - AGAAGAGGAGGAAGAGGAGGAGG 23 10977 BCL11A-9205 - AAGAAGAGGAGGAAGAGGAGGAGG 24 10978 BCL11A-9206 - ACCGGCGCAGCCACACGG 18 10979 BCL11A-9207 - CACCGGCGCAGCCACACGG 19 10980 BCL11A-3764 - GCACCGGCGCAGCCACACGG 20 10981 BCL11A-9208 - UGCACCGGCGCAGCCACACGG 21 10982 BCL11A-9209 - GUGCACCGGCGCAGCCACACGG 22 10983 BCL11A-9210 - GGUGCACCGGCGCAGCCACACGG 23 10984 BCL11A-9211 - UGGUGCACCGGCGCAGCCACACGG 24 10985 BCL11A-9212 - UAGAGCGCCUGGGGGCGG 18 10986 BCL11A-9213 - AUAGAGCGCCUGGGGGCGG 19 10987 BCL11A-9214 - CAUAGAGCGCCUGGGGGCGG 20 10988 BCL11A-9215 - GCAUAGAGCGCCUGGGGGCGG 21 10989 BCL11A-9216 - CGCAUAGAGCGCCUGGGGGCGG 22 10990 BCL11A-9217 - CCGCAUAGAGCGCCUGGGGGCGG 23 10991 BCL11A-9218 - ACCGCAUAGAGCGCCUGGGGGCGG 24 10992 BCL11A-9219 - AUGUGUGGCAGUUUUCGG 18 10993 BCL11A-9220 - GAUGUGUGGCAGUUUUCGG 19 10994 BCL11A-9221 - AGAUGUGUGGCAGUUUUCGG 20 10995 BCL11A-9222 - AAGAUGUGUGGCAGUUUUCGG 21 10996 BCL11A-9223 - CAAGAUGUGUGGCAGUUUUCGG 22 10997 BCL11A-9224 - UCAAGAUGUGUGGCAGUUUUCGG 23 10998 BCL11A-9225 - CUCAAGAUGUGUGGCAGUUUUCGG 24 10999 BCL11A-9226 - AAUUUGAAGCCCCCAGGG 18 11000 BCL11A-9227 - AAAUUUGAAGCCCCCAGGG 19 11001 BCL11A-9228 - AAAAUUUGAAGCCCCCAGGG 20 11002 BCL11A-9229 - GAAAAUUUGAAGCCCCCAGGG 21 11003 BCL11A-9230 - AGAAAAUUUGAAGCCCCCAGGG 22 11004 BCL11A-9231 - GAGAAAAUUUGAAGCCCCCAGGG 23 11005 BCL11A-9232 - UGAGAAAAUUUGAAGCCCCCAGGG 24 11006 BCL11A-9233 - GUGGACUACGGCUUCGGG 18 11007 BCL11A-9234 - GGUGGACUACGGCUUCGGG 19 11008 BCL11A-9235 - GGGUGGACUACGGCUUCGGG 20 11009 BCL11A-9236 - AGGGUGGACUACGGCUUCGGG 21 11010 BCL11A-9237 - GAGGGUGGACUACGGCUUCGGG 22 11011 BCL11A-9238 - AGAGGGUGGACUACGGCUUCGGG 23 11012 BCL11A-9239 - GAGAGGGUGGACUACGGCUUCGGG 24 11013 BCL11A-9240 - UGAUCCCGGAGAACGGGG 18 11014 BCL11A-9241 - CUGAUCCCGGAGAACGGGG 19 11015 BCL11A-9242 - CCUGAUCCCGGAGAACGGGG 20 11016 BCL11A-9243 - ACCUGAUCCCGGAGAACGGGG 21 11017 BCL11A-9244 - AACCUGAUCCCGGAGAACGGGG 22 11018 BCL11A-9245 - CAACCUGAUCCCGGAGAACGGGG 23 11019 BCL11A-9246 - CCAACCUGAUCCCGGAGAACGGGG 24 11020 BCL11A-9247 - GCAUAGAGCGCCUGGGGG 18 11021 BCL11A-9248 - CGCAUAGAGCGCCUGGGGG 19 11022 BCL11A-6143 - CCGCAUAGAGCGCCUGGGGG 20 11023 BCL11A-9249 - ACCGCAUAGAGCGCCUGGGGG 21 11024 BCL11A-9250 - CACCGCAUAGAGCGCCUGGGGG 22 11025 BCL11A-9251 - CCACCGCAUAGAGCGCCUGGGGG 23 11026 BCL11A-9252 - CCCACCGCAUAGAGCGCCUGGGGG 24 11027 BCL11A-9253 - CGCAUAGAGCGCCUGGGG 18 11028 BCL11A-9254 - CCGCAUAGAGCGCCUGGGG 19 11029 BCL11A-9255 - ACCGCAUAGAGCGCCUGGGG 20 11030 BCL11A-9256 - CACCGCAUAGAGCGCCUGGGG 21 11031 BCL11A-9257 - CCACCGCAUAGAGCGCCUGGGG 22 11032 BCL11A-9258 - CCCACCGCAUAGAGCGCCUGGGG 23 11033 BCL11A-9259 - CCCCACCGCAUAGAGCGCCUGGGG 24 11034 BCL11A-9260 - AUAAGCGCGGCCACCUGG 18 11035 BCL11A-9261 - CAUAAGCGCGGCCACCUGG 19 11036 BCL11A-9262 - GCAUAAGCGCGGCCACCUGG 20 11037 BCL11A-9263 - AGCAUAAGCGCGGCCACCUGG 21 11038 BCL11A-9264 - AAGCAUAAGCGCGGCCACCUGG 22 11039 BCL11A-9265 - GAAGCAUAAGCGCGGCCACCUGG 23 11040 BCL11A-9266 - AGAAGCAUAAGCGCGGCCACCUGG 24 11041 BCL11A-9267 - GAGAGGCUUCCGGCCUGG 18 11042 BCL11A-9268 - AGAGAGGCUUCCGGCCUGG 19 11043 BCL11A-9269 - GAGAGAGGCUUCCGGCCUGG 20 11044 BCL11A-9270 - CGAGAGAGGCUUCCGGCCUGG 21 11045 BCL11A-9271 - UCGAGAGAGGCUUCCGGCCUGG 22 11046 BCL11A-9272 - AUCGAGAGAGGCUUCCGGCCUGG 23 11047 BCL11A-9273 - UAUCGAGAGAGGCUUCCGGCCUGG 24 11048 BCL11A-9274 - CCUUCCACCAGGUCCUGG 18 11049 BCL11A-9275 - GCCUUCCACCAGGUCCUGG 19 11050 BCL11A-9276 - GGCCUUCCACCAGGUCCUGG 20 11051 BCL11A-9277 - AGGCCUUCCACCAGGUCCUGG 21 11052 BCL11A-9278 - GAGGCCUUCCACCAGGUCCUGG 22 11053 BCL11A-9279 - CGAGGCCUUCCACCAGGUCCUGG 23 11054 BCL11A-9280 - GCGAGGCCUUCCACCAGGUCCUGG 24 11055 BCL11A-9281 - GGAGACUUAGAGAGCUGG 18 11056 BCL11A-9282 - AGGAGACUUAGAGAGCUGG 19 11057 BCL11A-9283 - UAGGAGACUUAGAGAGCUGG 20 11058 BCL11A-9284 - CUAGGAGACUUAGAGAGCUGG 21 11059 BCL11A-9285 - UCUAGGAGACUUAGAGAGCUGG 22 11060 BCL11A-9286 - CUCUAGGAGACUUAGAGAGCUGG 23 11061 BCL11A-9287 - UCUCUAGGAGACUUAGAGAGCUGG 24 11062 BCL11A-9288 - CACCGCCCGGGGAGCUGG 18 11063 BCL11A-9289 - ACACCGCCCGGGGAGCUGG 19 11064 BCL11A-9290 - CACACCGCCCGGGGAGCUGG 20 11065 BCL11A-9291 - CCACACCGCCCGGGGAGCUGG 21 11066 BCL11A-9292 - UCCACACCGCCCGGGGAGCUGG 22 11067 BCL11A-9293 - CUCCACACCGCCCGGGGAGCUGG 23 11068 BCL11A-9294 - UCUCCACACCGCCCGGGGAGCUGG 24 11069 BCL11A-9295 - CAGCGGCACGGGAAGUGG 18 11070 BCL11A-9296 - GCAGCGGCACGGGAAGUGG 19 11071 BCL11A-6157 - CGCAGCGGCACGGGAAGUGG 20 11072 BCL11A-9297 - GCGCAGCGGCACGGGAAGUGG 21 11073 BCL11A-9298 - GGCGCAGCGGCACGGGAAGUGG 22 11074 BCL11A-9299 - GGGCGCAGCGGCACGGGAAGUGG 23 11075 BCL11A-9300 - GGGGCGCAGCGGCACGGGAAGUGG 24 11076 BCL11A-9301 - GCCCUGCCCGACGUCAUG 18 11077 BCL11A-9302 - CGCCCUGCCCGACGUCAUG 19 11078 BCL11A-9303 - GCGCCCUGCCCGACGUCAUG 20 11079 BCL11A-9304 - CGCGCCCUGCCCGACGUCAUG 21 11080 BCL11A-9305 - CCGCGCCCUGCCCGACGUCAUG 22 11081 BCL11A-9306 - GCCGCGCCCUGCCCGACGUCAUG 23 11082 BCL11A-9307 - AGCCGCGCCCUGCCCGACGUCAUG 24 11083 BCL11A-9308 - CGACACUUGUGAGUACUG 18 11084 BCL11A-9309 - GCGACACUUGUGAGUACUG 19 11085 BCL11A-6169 - AGCGACACUUGUGAGUACUG 20 11086 BCL11A-9310 - CAGCGACACUUGUGAGUACUG 21 11087 BCL11A-9311 - GCAGCGACACUUGUGAGUACUG 22 11088 BCL11A-9312 - CGCAGCGACACUUGUGAGUACUG 23 11089 BCL11A-9313 - ACGCAGCGACACUUGUGAGUACUG 24 11090 BCL11A-9314 - GAGGAGGAGGAGGAGCUG 18 11091 BCL11A-9315 - AGAGGAGGAGGAGGAGCUG 19 11092 BCL11A-9316 - AAGAGGAGGAGGAGGAGCUG 20 11093 BCL11A-9317 - GAAGAGGAGGAGGAGGAGCUG 21 11094 BCL11A-9318 - GGAAGAGGAGGAGGAGGAGCUG 22 11095 BCL11A-9319 - AGGAAGAGGAGGAGGAGGAGCUG 23 11096 BCL11A-9320 - GAGGAAGAGGAGGAGGAGGAGCUG 24 11097 BCL11A-9321 - CUGUCCAAAAAGCUGCUG 18 11098 BCL11A-9322 - CCUGUCCAAAAAGCUGCUG 19 11099 BCL11A-9323 - GCCUGUCCAAAAAGCUGCUG 20 11100 BCL11A-9324 - GGCCUGUCCAAAAAGCUGCUG 21 11101 BCL11A-9325 - GGGCCUGUCCAAAAAGCUGCUG 22 11102 BCL11A-9326 - GGGGCCUGUCCAAAAAGCUGCUG 23 11103 BCL11A-9327 - GGGGGCCUGUCCAAAAAGCUGCUG 24 11104 BCL11A-9328 - GCAGCGGCACGGGAAGUG 18 11105 BCL11A-9329 - CGCAGCGGCACGGGAAGUG 19 11106 BCL11A-9330 - GCGCAGCGGCACGGGAAGUG 20 11107 BCL11A-9331 - GGCGCAGCGGCACGGGAAGUG 21 11108 BCL11A-9332 - GGGCGCAGCGGCACGGGAAGUG 22 11109 BCL11A-9333 - GGGGCGCAGCGGCACGGGAAGUG 23 11110 BCL11A-9334 - CGGGGCGCAGCGGCACGGGAAGUG 24 11111 BCL11A-9335 - CCCGGCACCAGCGACUUG 18 11112 BCL11A-9336 - ACCCGGCACCAGCGACUUG 19 11113 BCL11A-9337 - AACCCGGCACCAGCGACUUG 20 11114 BCL11A-9338 - GAACCCGGCACCAGCGACUUG 21 11115 BCL11A-9339 - GGAACCCGGCACCAGCGACUUG 22 11116 BCL11A-9340 - CGGAACCCGGCACCAGCGACUUG 23 11117 BCL11A-9341 - CCGGAACCCGGCACCAGCGACUUG 24 11118 BCL11A-9342 - CUUAAGUUCUGAGAAAAU 18 11119 BCL11A-9343 - CCUUAAGUUCUGAGAAAAU 19 11120 BCL11A-9344 - CCCUUAAGUUCUGAGAAAAU 20 11121 BCL11A-9345 - GCCCUUAAGUUCUGAGAAAAU 21 11122 BCL11A-9346 - AGCCCUUAAGUUCUGAGAAAAU 22 11123 BCL11A-9347 - GAGCCCUUAAGUUCUGAGAAAAU 23 11124 BCL11A-9348 - AGAGCCCUUAAGUUCUGAGAAAAU 24 11125 BCL11A-9349 - GGAUUUCUCUAGGAGACU 18 11126 BCL11A-9350 - UGGAUUUCUCUAGGAGACU 19 11127 BCL11A-9351 - AUGGAUUUCUCUAGGAGACU 20 11128 BCL11A-9352 - CAUGGAUUUCUCUAGGAGACU 21 11129 BCL11A-9353 - CCAUGGAUUUCUCUAGGAGACU 22 11130 BCL11A-9354 - GCCAUGGAUUUCUCUAGGAGACU 23 11131 BCL11A-9355 - CGCCAUGGAUUUCUCUAGGAGACU 24 11132 BCL11A-9356 - AUGGAUUAAGAAUCUACU 18 11133 BCL11A-9357 - CAUGGAUUAAGAAUCUACU 19 11134 BCL11A-9358 - UCAUGGAUUAAGAAUCUACU 20 11135 BCL11A-9359 - CUCAUGGAUUAAGAAUCUACU 21 11136 BCL11A-9360 - ACUCAUGGAUUAAGAAUCUACU 22 11137 BCL11A-9361 - CACUCAUGGAUUAAGAAUCUACU 23 11138 BCL11A-9362 - ACACUCAUGGAUUAAGAAUCUACU 24 11139 BCL11A-9363 - GCGACACUUGUGAGUACU 18 11140 BCL11A-9364 - AGCGACACUUGUGAGUACU 19 11141 BCL11A-9365 - CAGCGACACUUGUGAGUACU 20 11142 BCL11A-9366 - GCAGCGACACUUGUGAGUACU 21 11143 BCL11A-9367 - CGCAGCGACACUUGUGAGUACU 22 11144 BCL11A-9368 - ACGCAGCGACACUUGUGAGUACU 23 11145 BCL11A-9369 - GACGCAGCGACACUUGUGAGUACU 24 11146 BCL11A-9370 - CCACCGCAUAGAGCGCCU 18 11147 BCL11A-9371 - CCCACCGCAUAGAGCGCCU 19 11148 BCL11A-6197 - CCCCACCGCAUAGAGCGCCU 20 11149 BCL11A-9372 - CCCCCACCGCAUAGAGCGCCU 21 11150 BCL11A-9373 - ACCCCCACCGCAUAGAGCGCCU 22 11151 BCL11A-9374 - GACCCCCACCGCAUAGAGCGCCU 23 11152 BCL11A-9375 - GGACCCCCACCGCAUAGAGCGCCU 24 11153 BCL11A-9376 - CCCCGGGCGAGUCGGCCU 18 11154 BCL11A-9377 - UCCCCGGGCGAGUCGGCCU 19 11155 BCL11A-6200 - CUCCCCGGGCGAGUCGGCCU 20 11156 BCL11A-9378 - GCUCCCCGGGCGAGUCGGCCU 21 11157 BCL11A-9379 - UGCUCCCCGGGCGAGUCGGCCU 22 11158 BCL11A-9380 - CUGCUCCCCGGGCGAGUCGGCCU 23 11159 BCL11A-9381 - GCUGCUCCCCGGGCGAGUCGGCCU 24 11160 BCL11A-9382 - CCUCGUCGGAGCACUCCU 18 11161 BCL11A-9383 - UCCUCGUCGGAGCACUCCU 19 11162 BCL11A-6202 - CUCCUCGUCGGAGCACUCCU 20 11163 BCL11A-9384 - CCUCCUCGUCGGAGCACUCCU 21 11164 BCL11A-9385 - GCCUCCUCGUCGGAGCACUCCU 22 11165 BCL11A-9386 - UGCCUCCUCGUCGGAGCACUCCU 23 11166 BCL11A-9387 - UUGCCUCCUCGUCGGAGCACUCCU 24 11167 BCL11A-9388 - AAGAUCCCUUCCUUAGCU 18 11168 BCL11A-9389 - AAAGAUCCCUUCCUUAGCU 19 11169 BCL11A-9390 - CAAAGAUCCCUUCCUUAGCU 20 11170 BCL11A-9391 - UCAAAGAUCCCUUCCUUAGCU 21 11171 BCL11A-9392 - CUCAAAGAUCCCUUCCUUAGCU 22 11172 BCL11A-9393 - GCUCAAAGAUCCCUUCCUUAGCU 23 11173 BCL11A-9394 - AGCUCAAAGAUCCCUUCCUUAGCU 24 11174 BCL11A-9395 - AGAGGGUGGACUACGGCU 18 11175 BCL11A-9396 - GAGAGGGUGGACUACGGCU 19 11176 BCL11A-9397 - CGAGAGGGUGGACUACGGCU 20 11177 BCL11A-9398 - GCGAGAGGGUGGACUACGGCU 21 11178 BCL11A-9399 - AGCGAGAGGGUGGACUACGGCU 22 11179 BCL11A-9400 - GAGCGAGAGGGUGGACUACGGCU 23 11180 BCL11A-9401 - AGAGCGAGAGGGUGGACUACGGCU 24 11181 BCL11A-9402 - CGGUUGAAUCCAAUGGCU 18 11182 BCL11A-9403 - GCGGUUGAAUCCAAUGGCU 19 11183 BCL11A-9404 - UGCGGUUGAAUCCAAUGGCU 20 11184 BCL11A-9405 - CUGCGGUUGAAUCCAAUGGCU 21 11185 BCL11A-9406 - GCUGCGGUUGAAUCCAAUGGCU 22 11186 BCL11A-9407 - UGCUGCGGUUGAAUCCAAUGGCU 23 11187 BCL11A-9408 - GUGCUGCGGUUGAAUCCAAUGGCU 24 11188 BCL11A-9409 - AGCUGGACGGAGGGAUCU 18 11189 BCL11A-9410 - GAGCUGGACGGAGGGAUCU 19 11190 BCL11A-6210 - GGAGCUGGACGGAGGGAUCU 20 11191 BCL11A-9411 - GGGAGCUGGACGGAGGGAUCU 21 11192 BCL11A-9412 - GGGGAGCUGGACGGAGGGAUCU 22 11193 BCL11A-9413 - CGGGGAGCUGGACGGAGGGAUCU 23 11194 BCL11A-9414 - CCGGGGAGCUGGACGGAGGGAUCU 24 11195 BCL11A-9415 - CCCGCCAUGGAUUUCUCU 18 11196 BCL11A-9416 - UCCCGCCAUGGAUUUCUCU 19 11197 BCL11A-6212 - CUCCCGCCAUGGAUUUCUCU 20 11198 BCL11A-9417 - CCUCCCGCCAUGGAUUUCUCU 21 11199 BCL11A-9418 - GCCUCCCGCCAUGGAUUUCUCU 22 11200 BCL11A-9419 - AGCCUCCCGCCAUGGAUUUCUCU 23 11201 BCL11A-9420 - GAGCCUCCCGCCAUGGAUUUCUCU 24 11202 BCL11A-9421 - CGAGAGCCCUUAAGUUCU 18 11203 BCL11A-9422 - UCGAGAGCCCUUAAGUUCU 19 11204 BCL11A-9423 - CUCGAGAGCCCUUAAGUUCU 20 11205 BCL11A-9424 - GCUCGAGAGCCCUUAAGUUCU 21 11206 BCL11A-9425 - AGCUCGAGAGCCCUUAAGUUCU 22 11207 BCL11A-9426 - AAGCUCGAGAGCCCUUAAGUUCU 23 11208 BCL11A-9427 - GAAGCUCGAGAGCCCUUAAGUUCU 24 11209 BCL11A-9428 - CGCCUUUUGCCUCCUCGU 18 11210 BCL11A-9429 - UCGCCUUUUGCCUCCUCGU 19 11211 BCL11A-6220 - AUCGCCUUUUGCCUCCUCGU 20 11212 BCL11A-9430 - AAUCGCCUUUUGCCUCCUCGU 21 11213 BCL11A-9431 - CAAUCGCCUUUUGCCUCCUCGU 22 11214 BCL11A-9432 - ACAAUCGCCUUUUGCCUCCUCGU 23 11215 BCL11A-9433 - GACAAUCGCCUUUUGCCUCCUCGU 24 11216 BCL11A-9434 - ACGCCCCAUAUUAGUGGU 18 11217 BCL11A-9435 - CACGCCCCAUAUUAGUGGU 19 11218 BCL11A-9436 - GCACGCCCCAUAUUAGUGGU 20 11219 BCL11A-9437 - AGCACGCCCCAUAUUAGUGGU 21 11220 BCL11A-9438 - GAGCACGCCCCAUAUUAGUGGU 22 11221 BCL11A-9439 - GGAGCACGCCCCAUAUUAGUGGU 23 11222 BCL11A-9440 - GGGAGCACGCCCCAUAUUAGUGGU 24 11223 BCL11A-9441 - GACACUUGUGAGUACUGU 18 11224 BCL11A-9442 - CGACACUUGUGAGUACUGU 19 11225 BCL11A-6230 - GCGACACUUGUGAGUACUGU 20 11226 BCL11A-9443 - AGCGACACUUGUGAGUACUGU 21 11227 BCL11A-9444 - CAGCGACACUUGUGAGUACUGU 22 11228 BCL11A-9445 - GCAGCGACACUUGUGAGUACUGU 23 11229 BCL11A-9446 - CGCAGCGACACUUGUGAGUACUGU 24 11230 BCL11A-9447 - CGCGGGUUGGUAUCCCUU 18 11231 BCL11A-9448 - CCGCGGGUUGGUAUCCCUU 19 11232 BCL11A-9449 - CCCGCGGGUUGGUAUCCCUU 20 11233 BCL11A-9450 - CCCCGCGGGUUGGUAUCCCUU 21 11234 BCL11A-9451 - ACCCCGCGGGUUGGUAUCCCUU 22 11235 BCL11A-9452 - GACCCCGCGGGUUGGUAUCCCUU 23 11236 BCL11A-9453 - UGACCCCGCGGGUUGGUAUCCCUU 24 11237 BCL11A-9454 - AGAUCCCUUCCUUAGCUU 18 11238 BCL11A-9455 - AAGAUCCCUUCCUUAGCUU 19 11239 BCL11A-6234 - AAAGAUCCCUUCCUUAGCUU 20 11240 BCL11A-9456 - CAAAGAUCCCUUCCUUAGCUU 21 11241 BCL11A-9457 - UCAAAGAUCCCUUCCUUAGCUU 22 11242 BCL11A-9458 - CUCAAAGAUCCCUUCCUUAGCUU 23 11243 BCL11A-9459 - GCUCAAAGAUCCCUUCCUUAGCUU 24 11244 BCL11A-9460 - CUCGAGAGCCCUUAAGUU 18 11245 BCL11A-9461 - GCUCGAGAGCCCUUAAGUU 19 11246 BCL11A-9462 - AGCUCGAGAGCCCUUAAGUU 20 11247 BCL11A-9463 - AAGCUCGAGAGCCCUUAAGUU 21 11248 BCL11A-9464 - GAAGCUCGAGAGCCCUUAAGUU 22 11249 BCL11A-9465 - GGAAGCUCGAGAGCCCUUAAGUU 23 11250 BCL11A-9466 - UGGAAGCUCGAGAGCCCUUAAGUU 24 11251 BCL11A-9467 - GGCAAGACGUUCAAAUUU 18 11252 BCL11A-9468 - CGGCAAGACGUUCAAAUUU 19 11253 BCL11A-9469 - GCGGCAAGACGUUCAAAUUU 20 11254 BCL11A-9470 - UGCGGCAAGACGUUCAAAUUU 21 11255 BCL11A-9471 - CUGCGGCAAGACGUUCAAAUUU 22 11256 BCL11A-9472 - UCUGCGGCAAGACGUUCAAAUUU 23 11257 BCL11A-9473 - UUCUGCGGCAAGACGUUCAAAUUU 24 11258

Table 17A provides exemplary targeting domains for knocking out the BCL11A gene selected according to the first tier parameters. The targeting domains bind within the first 500 bp of the coding sequence (e.g., within 500 bp downstream from the start codon) and have a high level of orthogonality. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 17A 1st Tier Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO: BCL11A-9474 + CGAUUGGUGAAGGGGAA 17 11259 BCL11A-9475 + AUUGGAUGCUUUUUUCA 17 11260 BCL11A-9476 − CAGGUCACGCCAGAGGA 17 11261 BCL11A-9477 + CUUACGCGAGAAUUCCC 17 11262 BCL11A-9478 + CCUGGAUGCCAACCUCC 17 11263 BCL11A-9479 − AACAAUGCAAUGGCAGC 17 11264 BCL11A-9480 + GGGGAAGGUGGCUUAUC 17 11265 BCL11A-9481 + GGUUCAUCAUCUGUAAG 17 11266 BCL11A-5334 + UGCACUCAUCCCAGGCG 17 11267 BCL11A-9482 + UUAAGUGCUGGGGUUUG 17 11268 BCL11A-9483 + CCAACCUCCACGGGAUU 17 11269 BCL11A-9484 + UCUCGAUUGGUGAAGGGGAA 20 11270 BCL11A-9485 + GGGAUUGGAUGCUUUUUUCA 20 11271 BCL11A-9486 − AUCCAGGUCACGCCAGAGGA 20 11272 BCL11A-9487 + UUACUUACGCGAGAAUUCCC 20 11273 BCL11A-6420 + UGACCUGGAUGCCAACCUCC 20 11274 BCL11A-9488 − GGAAACAAUGCAAUGGCAGC 20 11275 BCL11A-9489 + GAAGGGGAAGGUGGCUUAUC 20 11276 BCL11A-9490 + UCUGGUUCAUCAUCUGUAAG 20 11277 BCL11A-5480 + UUCUGCACUCAUCCCAGGCG 20 11278 BCL11A-9491 + UGCUUAAGUGCUGGGGUUUG 20 11279 BCL11A-9492 + AUGCCAACCUCCACGGGAUU 20 11280

Table 17B provides exemplary targeting domains for knocking out the BCL11A gene selected according to the third tier parameters. The targeting domains fall in the coding sequence of the gene, downstream of the first 500 bp of coding sequence (e.g., anywhere from +500 (relative to the start codon) to the stop codon of the gene). It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 17B 3rd Tier Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO: BCL11A-5515 + UCCGACGAGGAGGCAAA 17 11281 BCL11A-5520 − CUUCCGGCCUGGCAGAA 17 11282 BCL11A-9493 + UCCGUGUUCGCUUUCUA 17 11283 BCL11A-9494 − AGAGCGAGAGGGUGGAC 17 11284 BCL11A-9495 + CGGGAGGCUCCAUAGCC 17 11285 BCL11A-9496 − UUCCCAGCCACCUCUCC 17 11286 BCL11A-9497 + AGCUGGGGCUGCCCAGC 17 11287 BCL11A-9498 − GCUAUGGAGCCUCCCGC 17 11288 BCL11A-9499 + CGGCCAGGUGGCCGCGC 17 11289 BCL11A-9500 + GCGUCUUCAUGUGGCGC 17 11290 BCL11A-9501 + UCAGAACUUAAGGGCUC 17 11291 BCL11A-9502 − AGCUCAAAGAUCCCUUC 17 11292 BCL11A-9503 + GCAGGUCGAACUCCUUC 17 11293 BCL11A-9504 + GGGGCGUCGCCAGGAAG 17 11294 BCL11A-9505 − CCAGGAUCAGUAUCGAG 17 11295 BCL11A-9506 + GGCUGGGAGGGAGGAGG 17 11296 BCL11A-9507 + GACUUGACCGUCAUGGG 17 11297 BCL11A-9508 + CGGCCUCGGCCAGGUGG 17 11298 BCL11A-5799 + GCAUGUGCGUCUUCAUG 17 11299 BCL11A-9509 + CGCACAGGUUGCACUUG 17 11300 BCL11A-9510 + ACUCCUUCUCGAGCUUG 17 11301 BCL11A-9511 − AACACGCACAGAACACU 17 11302 BCL11A-9512 − CCUCGGAGAACGGGAGU 17 11303 BCL11A-9513 + GGUCAGGGGACUUCCGU 17 11304 BCL11A-5874 + UGCUCCGACGAGGAGGCAAA 20 11305 BCL11A-5879 − AGGCUUCCGGCCUGGCAGAA 20 11306 BCL11A-9514 + ACUUCCGUGUUCGCUUUCUA 20 11307 BCL11A-9515 − CGGAGAGCGAGAGGGUGGAC 20 11308 BCL11A-9516 + UGGCGGGAGGCUCCAUAGCC 20 11309 BCL11A-8754 − UCCUUCCCAGCCACCUCUCC 20 11310 BCL11A-9517 + GCGAGCUGGGGCUGCCCAGC 20 11311 BCL11A-9518 − AUGGCUAUGGAGCCUCCCGC 20 11312 BCL11A-9519 + CCUCGGCCAGGUGGCCGCGC 20 11313 BCL11A-9520 + UGUGCGUCUUCAUGUGGCGC 20 11314 BCL11A-7725 + UUCUCAGAACUUAAGGGCUC 20 11315 BCL11A-9521 − GGCAGCUCAAAGAUCCCUUC 20 11316 BCL11A-7752 + GGGGCAGGUCGAACUCCUUC 20 11317 BCL11A-9522 + GGGGGGGCGUCGCCAGGAAG 20 11318 BCL11A-9523 − AUACCAGGAUCAGUAUCGAG 20 11319 BCL11A-9524 + GGGGGCUGGGAGGGAGGAGG 20 11320 BCL11A-9525 + UCGGACUUGACCGUCAUGGG 20 11321 BCL11A-9526 + CCUCGGCCUCGGCCAGGUGG 20 11322 BCL11A-6165 + UGUGCAUGUGCGUCUUCAUG 20 11323 BCL11A-8204 + GGUCGCACAGGUUGCACUUG 20 11324 BCL11A-9527 + CGAACUCCUUCUCGAGCUUG 20 11325 BCL11A-9528 − UGCAACACGCACAGAACACU 20 11326 BCL11A-9529 − ACUCCUCGGAGAACGGGAGU 20 11327 BCL11A-9530 + CGGGGUCAGGGGACUUCCGU 20 11328

Table 18A provides exemplary targeting domains for knocking down the BCL11A gene selected according to the first tier parameters. The targeting domains bind within 500 bp (e.g., upstream or downstream) of a transcription start site (TSS) and have a high level of orthogonality. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL11A protein function, or the level of BCL11A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 18A 1st Tier Target SEQ DNA Site ID gRNA Name Strand Targeting Domain Length NO: BCL11A-9531 + AAGUGCAUACACGGCAA 17 11329 BCL11A-5319 + UUGCUUGCGGCGAGACA 17 11330 BCL11A-5320 − AUGUCUCGCCGCAAGCA 17 11331 BCL11A-9532 − UGACGUUCAAGUUCGCA 17 11332 BCL11A-9533 + UUGUGGGAGAGCCGUCA 17 11333 BCL11A-9534 + ACGGCAAUGGUUCCAGA 17 11334 BCL11A-9535 − GCGCUCGCUGCGGCCAC 17 11335 BCL11A-4560 + ACGCCAGACGCGGCCCC 17 11336 BCL11A-9536 + UUCACAUCGGGAGAGCC 17 11337 BCL11A-9537 + GUUCACAUCGGGAGAGC 17 11338 BCL11A-9538 − UAAUCACGAGAGCGCGC 17 11339 BCL11A-9539 − CUGACGUUCAAGUUCGC 17 11340 BCL11A-5327 + CCCGUUUGCUUAAGUGC 17 11341 BCL11A-9540 + ACGGCUCGGUUCACAUC 17 11342 BCL11A-9541 + CUUGAACGUCAGGAGUC 17 11343 BCL11A-9542 + CUGCGAACUUGAACGUC 17 11344 BCL11A-9543 − CCCCCGGGGGCCGCGUC 17 11345 BCL11A-9544 + UCCGCGGACGCCAGACG 17 11346 BCL11A-9545 − GACUAGAAGCAAAAGCG 17 11347 BCL11A-5335 + AGACAUGGUGGGCUGCG 17 11348 BCL11A-9546 − AAAACCUCCGAGAGUCG 17 11349 BCL11A-9547 + UUUACCUCGACUCUCGG 17 11350 BCL11A-9548 − AGUCCGCGUGUGUGGGG 17 11351 BCL11A-5336 + CGUUUGCUUAAGUGCUG 17 11352 BCL11A-9549 − UAGAGUCCGCGUGUGUG 17 11353 BCL11A-9550 + GACGGCUCGGUUCACAU 17 11354 BCL11A-9551 − CUCCCCGCACUGGCCAU 17 11355 BCL11A-9552 + CGGCAAUGGUUCCAGAU 17 11356 BCL11A-9553 + GCGGGCGGACGACGGCU 17 11357 BCL11A-5338 + CCGUUUGCUUAAGUGCU 17 11358 BCL11A-5340 + UUGCGGCGAGACAUGGU 17 11359 BCL11A-9554 + CGUGGCCGGGAGAGAAGAAA 20 11360 BCL11A-5345 + GCCUUGCUUGCGGCGAGACA 20 11361 BCL11A-5346 − ACCAUGUCUCGCCGCAAGCA 20 11362 BCL11A-9555 − UCCUGACGUUCAAGUUCGCA 20 11363 BCL11A-9556 + ACACCAAUGGACACACAUCA 20 11364 BCL11A-9557 + UACACGGCAAUGGUUCCAGA 20 11365 BCL11A-9558 + GCCAAUGGCCAGUGCGGGGA 20 11366 BCL11A-9559 + AAUGGUUCCAGAUGGGAUGA 20 11367 BCL11A-9560 − GAGUCUCCUUCUUUCUAACC 20 11368 BCL11A-9561 + CGGUUCACAUCGGGAGAGCC 20 11369 BCL11A-9562 + UCGGUUCACAUCGGGAGAGC 20 11370 BCL11A-9563 − CCGCGUGUGUGGGGGGGAGC 20 11371 BCL11A-9564 − UAAUAAUCACGAGAGCGCGC 20 11372 BCL11A-9565 + AAAUAAUACAAAGAUGGCGC 20 11373 BCL11A-9566 − CUCCUGACGUUCAAGUUCGC 20 11374 BCL11A-9567 + GAGACACACAAAACAUGGGC 20 11375 BCL11A-5352 + AUUCCCGUUUGCUUAAGUGC 20 11376 BCL11A-9568 + ACGACGGCUCGGUUCACAUC 20 11377 BCL11A-9569 − CGCACUUGAACUUGCAGCUC 20 11378 BCL11A-9570 + UCCCUGCGAACUUGAACGUC 20 11379 BCL11A-9571 − UCGAGGUAAAAGAGAUAAAG 20 11380 BCL11A-9572 + CCAAUGGCCAGUGCGGGGAG 20 11381 BCL11A-4351 + GACGCCAGACGCGGCCCCCG 20 11382 BCL11A-9573 − UGCGGCCACUGGUGAGCCCG 20 11383 BCL11A-9574 − GGGGCCGCGUCUGGCGUCCG 20 11384 BCL11A-5359 + GCGAGACAUGGUGGGCUGCG 20 11385 BCL11A-9575 − AGAAAAACCUCCGAGAGUCG 20 11386 BCL11A-4561 + ACGCCAGACGCGGCCCCCGG 20 11387 BCL11A-9576 + UCUUUUACCUCGACUCUCGG 20 11388 BCL11A-9577 − UAGAGUCCGCGUGUGUGGGG 20 11389 BCL11A-9578 − UUUAGAGUCCGCGUGUGUGG 20 11390 BCL11A-9579 + CAAUGGUUCCAGAUGGGAUG 20 11391 BCL11A-5361 + CGGCGAGACAUGGUGGGCUG 20 11392 BCL11A-9580 + CUGAGCUGCAAGUUCAAGUG 20 11393 BCL11A-9581 − CAUUUUAGAGUCCGCGUGUG 20 11394 BCL11A-9582 + GACGACGGCUCGGUUCACAU 20 11395 BCL11A-9583 − AGCCCCUGAUGUGUGUCCAU 20 11396 BCL11A-9584 + GCGGCGGGCGGACGACGGCU 20 11397 BCL11A-9585 + AUCUCUUUUACCUCGACUCU 20 11398 BCL11A-5365 + UGCUUGCGGCGAGACAUGGU 20 11399 BCL11A-9586 − AUUUUAGAGUCCGCGUGUGU 20 11400

Table 18B provides exemplary targeting domains for knocking down the BCL11A gene selected according to the second tier parameters. The targeting domains bind within 500 bp (e.g., upstream or downstream) of a transcription start site (TSS). It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL11A protein function, or the level of BCL11A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 18B 2nd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-9587 + GAGAGAGAUGAAAAAAA 17 11401 BCL11A-5369 - CCCAGCACUUAAGCAAA 17 11402 BCL11A-9588 - UUAUUUUGGAUGUCAAA 17 11403 BCL11A-4473 + GGCCGGGAGAGAAGAAA 17 11404 BCL11A-9589 + GCAGGGGUGGGAGGAAA 17 11405 BCL11A-9590 - GAGGUAAAAGAGAUAAA 17 11406 BCL11A-9591 + AAUUAAAUAAAAUUAAA 17 11407 BCL11A-9592 + GGGGAAGCUCACACCAA 17 11408 BCL11A-4574 + AGACCAGGACAAGCCAA 17 11409 BCL11A-9593 + UGGCCGGGAGAGAAGAA 17 11410 BCL11A-4491 + GGGCGAGCAGGAGAGAA 17 11411 BCL11A-9594 + GGCAGGGGUGGGAGGAA 17 11412 BCL11A-4570 + AGAAGGGGAGGAGGGAA 17 11413 BCL11A-9595 - CGAGGUAAAAGAGAUAA 17 11414 BCL11A-4625 + CAGAGACACACAAAACA 17 11415 BCL11A-9596 + UCUCAAAAGUGCAUACA 17 11416 BCL11A-9597 - GUGUGUGGGGGGGAGCA 17 11417 BCL11A-9598 + AAUACAAAGAUGGCGCA 17 11418 BCL11A-9599 + CACACAAAACAUGGGCA 17 11419 BCL11A-9600 + AGAAGAAAGGGGUGGCA 17 11420 BCL11A-9601 + CCAAUGGACACACAUCA 17 11421 BCL11A-9602 - CUUGAACUUGCAGCUCA 17 11422 BCL11A-4529 + AAAAAAAAAAAAAAAGA 17 11423 BCL11A-9603 + UAGAAAUAAUACAAAGA 17 11424 BCL11A-9604 + GAGCCGGGUUAGAAAGA 17 11425 BCL11A-4592 + AGGGCGAGCAGGAGAGA 17 11426 BCL11A-4534 - AAAGCGAGGGGGAGAGA 17 11427 BCL11A-9605 + GAGAGAAGAGAGAUAGA 17 11428 BCL11A-4674 + CGGCGGCGGGCGGACGA 17 11429 BCL11A-4494 + GGGGAGGGGCGGGCCGA 17 11430 BCL11A-9606 - ACUAGAAGCAAAAGCGA 17 11431 BCL11A-4591 + AGGAGAGAAGGGGAGGA 17 11432 BCL11A-4399 + GAGAAGGGGAGGAGGGA 17 11433 BCL11A-4499 + GGGGCGGGCCGAGGGGA 17 11434 BCL11A-9607 + AAUGGCCAGUGCGGGGA 17 11435 BCL11A-4562 + ACGCGGCCCCCGGGGGA 17 11436 BCL11A-9608 + AACGUCAGGAGUCUGGA 17 11437 BCL11A-9609 - UUAAAAAAAAGCCAUGA 17 11438 BCL11A-9610 + GGUUCCAGAUGGGAUGA 17 11439 BCL11A-5383 - CCAGCACUUAAGCAAAC 17 11440 BCL11A-9611 - CCUCCCCCUCCCCGCAC 17 11441 BCL11A-9612 - UCUCCUUCUUUCUAACC 17 11442 BCL11A-9613 + GACAUGAAAAAGAGACC 17 11443 BCL11A-4662 + CGCCAGACGCGGCCCCC 17 11444 BCL11A-9614 - CGGCCCGCCCCUCCCCC 17 11445 BCL11A-9615 - UCGGCCCGCCCCUCCCC 17 11446 BCL11A-9616 + GCGGCGGUGGCGUGGCC 17 11447 BCL11A-9617 - ACCCCUUUCUUCUCUCC 17 11448 BCL11A-9618 - UGGCCAUUGGCUUGUCC 17 11449 BCL11A-9619 + ACAUGGGCAGGGCGAGC 17 11450 BCL11A-9620 - CGUGUGUGGGGGGGAGC 17 11451 BCL11A-9621 + GGGGGCGCUGGGGCCGC 17 11452 BCL11A-4646 + CCGAGGGGAGGGGGCGC 17 11453 BCL11A-9622 + UAAUACAAAGAUGGCGC 17 11454 BCL11A-4441 + GCGGCGGCGGCGGCGGC 17 11455 BCL11A-9623 + GGACACACAUCAGGGGC 17 11456 BCL11A-4429 + GCCCCCGGGGGAGGGGC 17 11457 BCL11A-5392 + AUGGUGGGCUGCGGGGC 17 11458 BCL11A-9624 + AGGGGGAGGUGCGGGGC 17 11459 BCL11A-9625 + ACACACAAAACAUGGGC 17 11460 BCL11A-9626 + CGCGGCGGUGGCGUGGC 17 11461 BCL11A-9627 + GAGAAGAAAGGGGUGGC 17 11462 BCL11A-5395 + GAGACAUGGUGGGCUGC 17 11463 BCL11A-9628 + AAGCCAAUGGCCAGUGC 17 11464 BCL11A-9629 + CGGGGAGGGGGAGGUGC 17 11465 BCL11A-9630 + ACCAAUGGACACACAUC 17 11466 BCL11A-9631 - AAAACCCUCAUCCCAUC 17 11467 BCL11A-9632 - ACUUGAACUUGCAGCUC 17 11468 BCL11A-9633 - GAUGAAGAUAUUUUCUC 17 11469 BCL11A-4528 + AAAAAAAAAAAAAAAAG 17 11470 BCL11A-4433 + GCCGGGAGAGAAGAAAG 17 11471 BCL11A-9634 - AGGUAAAAGAGAUAAAG 17 11472 BCL11A-4475 + GGCGAGCAGGAGAGAAG 17 11473 BCL11A-4389 + GAAGGGGAGGAGGGAAG 17 11474 BCL11A-9635 + GGCCGCGGGCUCACCAG 17 11475 BCL11A-9636 + GAAGAAAGGGGUGGCAG 17 11476 BCL11A-9637 + CAAUGGACACACAUCAG 17 11477 BCL11A-9638 - UUGAACUUGCAGCUCAG 17 11478 BCL11A-4543 - AAGCGAGGGGGAGAGAG 17 11479 BCL11A-4533 - AAAAGCGAGGGGGAGAG 17 11480 BCL11A-4485 + GGGAGGGGCGGGCCGAG 17 11481 BCL11A-9639 - CUAGAAGCAAAAGCGAG 17 11482 BCL11A-4492 + GGGCGGGCCGAGGGGAG 17 11483 BCL11A-9640 + AUGGCCAGUGCGGGGAG 17 11484 BCL11A-4665 + CGCGGCCCCCGGGGGAG 17 11485 BCL11A-9641 + AGAGAGAAGAGAGAUAG 17 11486 BCL11A-9642 + GCUCCCCCCCACACACG 17 11487 BCL11A-4427 + GCCAGACGCGGCCCCCG 17 11488 BCL11A-9643 - GGCCCGCCCCUCCCCCG 17 11489 BCL11A-9644 - GGCCACUGGUGAGCCCG 17 11490 BCL11A-4670 - CGGCCACGCCACCGCCG 17 11491 BCL11A-4470 + GGCCGCAGCGAGCGCCG 17 11492 BCL11A-4502 + GGGGGAGGGGCGGGCCG 17 11493 BCL11A-9645 + AGGGGGCGCUGGGGCCG 17 11494 BCL11A-9646 + CGGGGCGGGGGGCUCCG 17 11495 BCL11A-9647 - GCCGCGUCUGGCGUCCG 17 11496 BCL11A-9648 + GGGGGAGGUGCGGGGCG 17 11497 BCL11A-9649 + GCGCCGCGGCGGUGGCG 17 11498 BCL11A-9650 + AGCCAAUGGCCAGUGCG 17 11499 BCL11A-9651 + GGGGAGGGGGAGGUGCG 17 11500 BCL11A-9652 - GGUAAAAGAGAUAAAGG 17 11501 BCL11A-9653 - UGAACUUGCAGCUCAGG 17 11502 BCL11A-9654 - UAGAAGCAAAAGCGAGG 17 11503 BCL11A-4627 + CAGGAGAGAAGGGGAGG 17 11504 BCL11A-4480 + GGCGGGCCGAGGGGAGG 17 11505 BCL11A-9655 + UGGCCAGUGCGGGGAGG 17 11506 BCL11A-4634 + CCAGACGCGGCCCCCGG 17 11507 BCL11A-9656 - GCCCGCCCCUCCCCCGG 17 11508 BCL11A-4660 + CGCAGCGAGCGCCGCGG 17 11509 BCL11A-4588 + AGCGAGCGCCGCGGCGG 17 11510 BCL11A-4478 + GGCGGCGGCGGCGGCGG 17 11511 BCL11A-4447 + GCGGGCGGCGGCGGCGG 17 11512 BCL11A-4500 + GGGGCGGGCGGCGGCGG 17 11513 BCL11A-5409 + UGCGGGGCGGGCGGCGG 17 11514 BCL11A-5410 + GGCUGCGGGGCGGGCGG 17 11515 BCL11A-9657 + GGGGAGGUGCGGGGCGG 17 11516 BCL11A-9658 + GGGGUGGGAGGAAAGGG 17 11517 BCL11A-9659 - GAACUUGCAGCUCAGGG 17 11518 BCL11A-4444 + GCGGCGGCGGCGGCGGG 17 11519 BCL11A-5411 + GUGGGCUGCGGGGCGGG 17 11520 BCL11A-9660 + GGGAGGUGCGGGGCGGG 17 11521 BCL11A-4483 + GGGAGAGAAGAAAGGGG 17 11522 BCL11A-4407 + GAGCAGGAGAGAAGGGG 17 11523 BCL11A-9661 + GAAAGGGGUGGCAGGGG 17 11524 BCL11A-4593 + AGGGGCGGGCCGAGGGG 17 11525 BCL11A-4467 + GGCCCCCGGGGGAGGGG 17 11526 BCL11A-5413 + CAUGGUGGGCUGCGGGG 17 11527 BCL11A-9662 + CAAUGGCCAGUGCGGGG 17 11528 BCL11A-9663 + GAGGGGGAGGUGCGGGG 17 11529 BCL11A-9664 + CCAGUGCGGGGAGGGGG 17 11530 BCL11A-4395 + GACGCGGCCCCCGGGGG 17 11531 BCL11A-9665 + GGGAGGAAAGGGUGGGG 17 11532 BCL11A-9666 + UGGGAGGAAAGGGUGGG 17 11533 BCL11A-9667 + GGGGUGGCAGGGGUGGG 17 11534 BCL11A-9668 - GAGUCCGCGUGUGUGGG 17 11535 BCL11A-5414 + CUUGCGGCGAGACAUGG 17 11536 BCL11A-9669 + GUGGGAGGAAAGGGUGG 17 11537 BCL11A-9670 - AGAGUCCGCGUGUGUGG 17 11538 BCL11A-9671 + UGGUUCCAGAUGGGAUG 17 11539 BCL11A-9672 + GAGGGGAGGGGGCGCUG 17 11540 BCL11A-9673 - CGCCGCGGCGCUCGCUG 17 11541 BCL11A-5422 + CGAGACAUGGUGGGCUG 17 11542 BCL11A-9674 + AGCUGCAAGUUCAAGUG 17 11543 BCL11A-9675 + CAAGCCAAUGGCCAGUG 17 11544 BCL11A-9676 + GCGGGGAGGGGGAGGUG 17 11545 BCL11A-9677 + GGUGGGAGGAAAGGGUG 17 11546 BCL11A-9678 - UUUAGAGUCCGCGUGUG 17 11547 BCL11A-9679 + GCAGGGAAGAUGAAUUG 17 11548 BCL11A-5426 + GGGGUUUGCCUUGCUUG 17 11549 BCL11A-9680 + AGAGACACACAAAACAU 17 11550 BCL11A-9681 - CCCUGAUGUGUGUCCAU 17 11551 BCL11A-5431 + AUUAUUAUUACUAUUAU 17 11552 BCL11A-9682 - CCAGCGCCCCCUCCCCU 17 11553 BCL11A-9683 + CGAGGGGAGGGGGCGCU 17 11554 BCL11A-9684 + UCUUUUACCUCGACUCU 17 11555 BCL11A-9685 + GGGUGGGAGGAAAGGGU 17 11556 BCL11A-9686 + AAAGGGGUGGCAGGGGU 17 11557 BCL11A-9687 - UUAGAGUCCGCGUGUGU 17 11558 BCL11A-9688 + CAGGGAAGAUGAAUUGU 17 11559 BCL11A-5439 + UUAUUAUUACUAUUAUU 17 11560 BCL11A-9689 - UUAUUUCUAAUUUAUUU 17 11561 BCL11A-9690 + AGAGAGAGAGAUGAAAAAAA 20 11562 BCL11A-5443 - AACCCCAGCACUUAAGCAAA 20 11563 BCL11A-9691 - AAUUUAUUUUGGAUGUCAAA 20 11564 BCL11A-9692 + GUGGCAGGGGUGGGAGGAAA 20 11565 BCL11A-9693 - GUCGAGGUAAAAGAGAUAAA 20 11566 BCL11A-9694 + UAAAAUUAAAUAAAAUUAAA 20 11567 BCL11A-9695 + GAAGGGGAAGCUCACACCAA 20 11568 BCL11A-4541 + AAGAGACCAGGACAAGCCAA 20 11569 BCL11A-9696 + CAAAAGUGCAUACACGGCAA 20 11570 BCL11A-9697 + GCGUGGCCGGGAGAGAAGAA 20 11571 BCL11A-4422 + GCAGGGCGAGCAGGAGAGAA 20 11572 BCL11A-9698 + GGUGGCAGGGGUGGGAGGAA 20 11573 BCL11A-4404 + GAGAGAAGGGGAGGAGGGAA 20 11574 BCL11A-9699 - AGUCGAGGUAAAAGAGAUAA 20 11575 BCL11A-4455 + GGACAGAGACACACAAAACA 20 11576 BCL11A-9700 + CUGUCUCAAAAGUGCAUACA 20 11577 BCL11A-9701 - CGCGUGUGUGGGGGGGAGCA 20 11578 BCL11A-9702 + AAUAAUACAAAGAUGGCGCA 20 11579 BCL11A-9703 + AGACACACAAAACAUGGGCA 20 11580 BCL11A-9704 + GAGAGAAGAAAGGGGUGGCA 20 11581 BCL11A-9705 - GCACUUGAACUUGCAGCUCA 20 11582 BCL11A-9706 + GAAUUGUGGGAGAGCCGUCA 20 11583 BCL11A-4527 + AAAAAAAAAAAAAAAAAAGA 20 11584 BCL11A-9707 + AAUUAGAAAUAAUACAAAGA 20 11585 BCL11A-9708 + GGAGAGCCGGGUUAGAAAGA 20 11586 BCL11A-4464 + GGCAGGGCGAGCAGGAGAGA 20 11587 BCL11A-4418 - GCAAAAGCGAGGGGGAGAGA 20 11588 BCL11A-9709 + AGAGAGAGAAGAGAGAUAGA 20 11589 BCL11A-4673 + CGGCGGCGGCGGGCGGACGA 20 11590 BCL11A-4648 + CCGGGGGAGGGGCGGGCCGA 20 11591 BCL11A-9710 - AGGACUAGAAGCAAAAGCGA 20 11592 BCL11A-4584 + AGCAGGAGAGAAGGGGAGGA 20 11593 BCL11A-4459 + GGAGAGAAGGGGAGGAGGGA 20 11594 BCL11A-4461 + GGAGGGGCGGGCCGAGGGGA 20 11595 BCL11A-4624 + CAGACGCGGCCCCCGGGGGA 20 11596 BCL11A-9711 + UUGAACGUCAGGAGUCUGGA 20 11597 BCL11A-9712 - UGCUUAAAAAAAAGCCAUGA 20 11598 BCL11A-5458 - ACCCCAGCACUUAAGCAAAC 20 11599 BCL11A-9713 - GCGGCGCUCGCUGCGGCCAC 20 11600 BCL11A-9714 - GCACCUCCCCCUCCCCGCAC 20 11601 BCL11A-9715 + CUGGACAUGAAAAAGAGACC 20 11602 BCL11A-4456 + GGACGCCAGACGCGGCCCCC 20 11603 BCL11A-9716 - CCUCGGCCCGCCCCUCCCCC 20 11604 BCL11A-4362 + CGGACGCCAGACGCGGCCCC 20 11605 BCL11A-9717 - CCCUCGGCCCGCCCCUCCCC 20 11606 BCL11A-9718 + GCCGCGGCGGUGGCGUGGCC 20 11607 BCL11A-9719 - GCCACCCCUUUCUUCUCUCC 20 11608 BCL11A-9720 - CACUGGCCAUUGGCUUGUCC 20 11609 BCL11A-9721 + AAAACAUGGGCAGGGCGAGC 20 11610 BCL11A-9722 + GGAGGGGGCGCUGGGGCCGC 20 11611 BCL11A-4490 + GGGCCGAGGGGAGGGGGCGC 20 11612 BCL11A-4442 + GCGGCGGCGGCGGCGGCGGC 20 11613 BCL11A-9723 + AAUGGACACACAUCAGGGGC 20 11614 BCL11A-4439 + GCGGCCCCCGGGGGAGGGGC 20 11615 BCL11A-5465 + GACAUGGUGGGCUGCGGGGC 20 11616 BCL11A-9724 + GGGAGGGGGAGGUGCGGGGC 20 11617 BCL11A-9725 + CGCCGCGGCGGUGGCGUGGC 20 11618 BCL11A-9726 + GGAGAGAAGAAAGGGGUGGC 20 11619 BCL11A-5468 + GGCGAGACAUGGUGGGCUGC 20 11620 BCL11A-9727 + GACAAGCCAAUGGCCAGUGC 20 11621 BCL11A-9728 + GUGCGGGGAGGGGGAGGUGC 20 11622 BCL11A-9729 + CACACCAAUGGACACACAUC 20 11623 BCL11A-9730 - GAAAAAACCCUCAUCCCAUC 20 11624 BCL11A-9731 - ACUGAUGAAGAUAUUUUCUC 20 11625 BCL11A-9732 + GAACUUGAACGUCAGGAGUC 20 11626 BCL11A-9733 - CCUCCCCCGGGGGCCGCGUC 20 11627 BCL11A-4526 + AAAAAAAAAAAAAAAAAAAG 20 11628 BCL11A-9734 + GUGGCCGGGAGAGAAGAAAG 20 11629 BCL11A-4629 + CAGGGCGAGCAGGAGAGAAG 20 11630 BCL11A-4577 + AGAGAAGGGGAGGAGGGAAG 20 11631 BCL11A-9735 + UGGGGCCGCGGGCUCACCAG 20 11632 BCL11A-9736 + AGAGAAGAAAGGGGUGGCAG 20 11633 BCL11A-9737 + CACCAAUGGACACACAUCAG 20 11634 BCL11A-9738 - CACUUGAACUUGCAGCUCAG 20 11635 BCL11A-4611 - CAAAAGCGAGGGGGAGAGAG 20 11636 BCL11A-4583 - AGCAAAAGCGAGGGGGAGAG 20 11637 BCL11A-4677 + CGGGGGAGGGGCGGGCCGAG 20 11638 BCL11A-9739 - GGACUAGAAGCAAAAGCGAG 20 11639 BCL11A-4411 + GAGGGGCGGGCCGAGGGGAG 20 11640 BCL11A-4575 + AGACGCGGCCCCCGGGGGAG 20 11641 BCL11A-9740 + GAGAGAGAGAAGAGAGAUAG 20 11642 BCL11A-9741 + CCUGCUCCCCCCCACACACG 20 11643 BCL11A-9742 + GGCUCCGCGGACGCCAGACG 20 11644 BCL11A-9743 - CUCGGCCCGCCCCUCCCCCG 20 11645 BCL11A-9744 - UCCCGGCCACGCCACCGCCG 20 11646 BCL11A-9745 + AGUGGCCGCAGCGAGCGCCG 20 11647 BCL11A-4642 + CCCGGGGGAGGGGCGGGCCG 20 11648 BCL11A-9746 + GGGAGGGGGCGCUGGGGCCG 20 11649 BCL11A-9747 + GUGCGGGGCGGGGGGCUCCG 20 11650 BCL11A-9748 - CAGGACUAGAAGCAAAAGCG 20 11651 BCL11A-9749 + GGAGGGGGAGGUGCGGGGCG 20 11652 BCL11A-9750 + CGAGCGCCGCGGCGGUGGCG 20 11653 BCL11A-9751 + ACAAGCCAAUGGCCAGUGCG 20 11654 BCL11A-9752 + UGCGGGGAGGGGGAGGUGCG 20 11655 BCL11A-9753 - CGAGGUAAAAGAGAUAAAGG 20 11656 BCL11A-9754 - ACUUGAACUUGCAGCUCAGG 20 11657 BCL11A-9755 - GACUAGAAGCAAAAGCGAGG 20 11658 BCL11A-4408 + GAGCAGGAGAGAAGGGGAGG 20 11659 BCL11A-4594 + AGGGGCGGGCCGAGGGGAGG 20 11660 BCL11A-9756 + CAAUGGCCAGUGCGGGGAGG 20 11661 BCL11A-9757 - UCGGCCCGCCCCUCCCCCGG 20 11662 BCL11A-4471 + GGCCGCAGCGAGCGCCGCGG 20 11663 BCL11A-4661 + CGCAGCGAGCGCCGCGGCGG 20 11664 BCL11A-4479 + GGCGGCGGCGGCGGCGGCGG 20 11665 BCL11A-4448 + GCGGGCGGCGGCGGCGGCGG 20 11666 BCL11A-4501 + GGGGCGGGCGGCGGCGGCGG 20 11667 BCL11A-5484 + UGCGGGGCGGGCGGCGGCGG 20 11668 BCL11A-5485 + GGCUGCGGGGCGGGCGGCGG 20 11669 BCL11A-5486 + GUGGGCUGCGGGGCGGGCGG 20 11670 BCL11A-9758 + GAGGGGGAGGUGCGGGGCGG 20 11671 BCL11A-9759 + GCAGGGGUGGGAGGAAAGGG 20 11672 BCL11A-9760 - CUUGAACUUGCAGCUCAGGG 20 11673 BCL11A-4443 + GCGGCGGCGGCGGCGGCGGG 20 11674 BCL11A-5487 + AUGGUGGGCUGCGGGGCGGG 20 11675 BCL11A-9761 + AGGGGGAGGUGCGGGGCGGG 20 11676 BCL11A-4434 + GCCGGGAGAGAAGAAAGGGG 20 11677 BCL11A-4476 + GGCGAGCAGGAGAGAAGGGG 20 11678 BCL11A-9762 + GAAGAAAGGGGUGGCAGGGG 20 11679 BCL11A-4486 + GGGAGGGGCGGGCCGAGGGG 20 11680 BCL11A-4666 + CGCGGCCCCCGGGGGAGGGG 20 11681 BCL11A-5489 + AGACAUGGUGGGCUGCGGGG 20 11682 BCL11A-9763 + AGCCAAUGGCCAGUGCGGGG 20 11683 BCL11A-9764 + GGGGAGGGGGAGGUGCGGGG 20 11684 BCL11A-9765 + UGGCCAGUGCGGGGAGGGGG 20 11685 BCL11A-4635 + CCAGACGCGGCCCCCGGGGG 20 11686 BCL11A-9766 + GGUGGGAGGAAAGGGUGGGG 20 11687 BCL11A-9767 + GGGUGGGAGGAAAGGGUGGG 20 11688 BCL11A-9768 + AAAGGGGUGGCAGGGGUGGG 20 11689 BCL11A-9769 - UUAGAGUCCGCGUGUGUGGG 20 11690 BCL11A-5490 + UUGCUUGCGGCGAGACAUGG 20 11691 BCL11A-9770 + GGGGUGGGAGGAAAGGGUGG 20 11692 BCL11A-9771 + GCCGAGGGGAGGGGGCGCUG 20 11693 BCL11A-9772 - CACCGCCGCGGCGCUCGCUG 20 11694 BCL11A-5497 + UCCCGUUUGCUUAAGUGCUG 20 11695 BCL11A-9773 + GGACAAGCCAAUGGCCAGUG 20 11696 BCL11A-9774 + AGUGCGGGGAGGGGGAGGUG 20 11697 BCL11A-9775 + AGGGGUGGGAGGAAAGGGUG 20 11698 BCL11A-9776 - UUUUAGAGUCCGCGUGUGUG 20 11699 BCL11A-9777 + GGCGCAGGGAAGAUGAAUUG 20 11700 BCL11A-5500 + GCUGGGGUUUGCCUUGCUUG 20 11701 BCL11A-9778 + GACAGAGACACACAAAACAU 20 11702 BCL11A-9779 - CCCCUCCCCGCACUGGCCAU 20 11703 BCL11A-9780 + ACACGGCAAUGGUUCCAGAU 20 11704 BCL11A-9781 + AUAAUUAUUAUUACUAUUAU 20 11705 BCL11A-9782 - GCCCCAGCGCCCCCUCCCCU 20 11706 BCL11A-9783 + GGCCGAGGGGAGGGGGCGCU 20 11707 BCL11A-5509 + UUCCCGUUUGCUUAAGUGCU 20 11708 BCL11A-9784 + CAGGGGUGGGAGGAAAGGGU 20 11709 BCL11A-9785 + AAGAAAGGGGUGGCAGGGGU 20 11710 BCL11A-9786 + GCGCAGGGAAGAUGAAUUGU 20 11711 BCL11A-9787 + UAAUUAUUAUUACUAUUAUU 20 11712 BCL11A-9788 - GUAUUAUUUCUAAUUUAUUU 20 11713

Table 18C provides exemplary targeting domains for knocking down the BCL11A gene selected according to the third tier parameters. The targeting domains binds within the additional 500 bp (e.g., upstream or downstream) of a transcription start site (TSS), e.g., extending to 1 kb upstream and downstream of a TSS. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL11A protein function, or the level of BCL11A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 18C DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-9789 - CACUCACCGUAAGAAAA 17 11714 BCL11A-9790 + CCUCUGGCCGGAACAAA 17 11715 BCL11A-9791 + CGAGGAGCCGGCACAAA 17 11716 BCL11A-9792 - UAUUUCUCUUUUCGAAA 17 11717 BCL11A-9793 - GGGAGCUGGUGGGGAAA 17 11718 BCL11A-9794 - AAGUGGCACUGUGGAAA 17 11719 BCL11A-9795 + GGGCUGCGGGUCCGGAA 17 11720 BCL11A-9796 + GAAAUAAAGCGGCGGAA 17 11721 BCL11A-9797 - UGGGAGCUGGUGGGGAA 17 11722 BCL11A-9798 - AAAGUGGCACUGUGGAA 17 11723 BCL11A-9799 + GCCCGAGGGCGCCCCCA 17 11724 BCL11A-9800 + CGUCCUUCCCGGUCCCA 17 11725 BCL11A-9801 + CCCCCAAGGCCGAGCCA 17 11726 BCL11A-9802 + CCCGCGUGUGGACGCCA 17 11727 BCL11A-9597 - GUGUGUGGGGGGGAGCA 17 11728 BCL11A-9803 + AGGUGGGAGGGAGCGCA 17 11729 BCL11A-9804 - GGACACCAGCGCGCUCA 17 11730 BCL11A-9805 + CGCGCGGCCUGGAAAGA 17 11731 BCL11A-9806 - UCCGCGGAGUCGGGAGA 17 11732 BCL11A-9807 + CGCAGGCCGGGGCCCGA 17 11733 BCL11A-9808 - GAGAGGGGCCGCGGCGA 17 11734 BCL11A-9809 + AGCUCCGCAGCGGGCGA 17 11735 BCL11A-9810 - CGUGGGACCGGGAAGGA 17 11736 BCL11A-9811 - GGUGUGCGUACGGAGGA 17 11737 BCL11A-9812 + AGGGCUGCGGGUCCGGA 17 11738 BCL11A-9813 + GGGGAAGCGCGGGCGGA 17 11739 BCL11A-9814 - AAAUGGGGGGGUAGGGA 17 11740 BCL11A-9815 - GAGCCGUGGGACCGGGA 17 11741 BCL11A-9816 - CGCGGCGGCGGCGGGGA 17 11742 BCL11A-9817 + GGCGAGGGGAGGUGGGA 17 11743 BCL11A-9818 + UCCAGCCUAAGUUUGGA 17 11744 BCL11A-9819 - AAUAAUGAACAAUGCUA 17 11745 BCL11A-9820 - GGAAGUGGGUGUGCGUA 17 11746 BCL11A-9821 - AAGAAAAUGGGGGGGUA 17 11747 BCL11A-9822 + ACCCCCCCAUUUUCUUA 17 11748 BCL11A-9823 + UCAUUAUUUUGCAAAAC 17 11749 BCL11A-9824 + AUAGAGCGAGAGUGCAC 17 11750 BCL11A-9825 - GAGAAAAGAGGUGAGAC 17 11751 BCL11A-9826 - AGAGGGGCCGCGGCGAC 17 11752 BCL11A-9827 - GUGGGACCGGGAAGGAC 17 11753 BCL11A-9828 + AAGGCCGAGCCAGGGAC 17 11754 BCL11A-9829 + GCCUGGAAAGAGGGGAC 17 11755 BCL11A-9830 - GGGGAGAGCCGUGGGAC 17 11756 BCL11A-9831 - CAACUCACAUGCAAACC 17 11757 BCL11A-9832 + UAGAGCGAGAGUGCACC 17 11758 BCL11A-9833 + AGGCCGAGCCAGGGACC 17 11759 BCL11A-9834 + CCUGGAAAGAGGGGACC 17 11760 BCL11A-9835 - GGGAGAGCCGUGGGACC 17 11761 BCL11A-9836 - CCGGGAGCAACUCUACC 17 11762 BCL11A-9837 + CACCAGCUCCCACCCCC 17 11763 BCL11A-9838 + CGGGAGGCUGCAGCCCC 17 11764 BCL11A-9839 - GCUUUUACUUCGGCCCC 17 11765 BCL11A-9840 - CUGUGGAAAGGGGCCCC 17 11766 BCL11A-9841 + UCACCUCUUUUCUCCCC 17 11767 BCL11A-9842 - CCGCGCUUCCCCAGCCC 17 11768 BCL11A-9843 + CCGGGAGGCUGCAGCCC 17 11769 BCL11A-9844 - GGGGCGCCCUCGGGCCC 17 11770 BCL11A-9845 - CGCCGCCUGCCUCUCCC 17 11771 BCL11A-9846 + CUCACCUCUUUUCUCCC 17 11772 BCL11A-9847 - UCUAAAAAACGAUUCCC 17 11773 BCL11A-9848 + GCGGGCGGAGGGAAGCC 17 11774 BCL11A-9849 - CCCGCGCUUCCCCAGCC 17 11775 BCL11A-9850 + GCCCCCAAGGCCGAGCC 17 11776 BCL11A-9851 + CCCCGCGUGUGGACGCC 17 11777 BCL11A-9852 + GCGGACUCAGGAGCGCC 17 11778 BCL11A-9853 + GGCAGGCGGCGCAGGCC 17 11779 BCL11A-9854 + CAGGAGCCCGCGCGGCC 17 11780 BCL11A-9855 - CCGGGGCUGCAGCCUCC 17 11781 BCL11A-9856 - CAGGCCGCGCGGGCUCC 17 11782 BCL11A-9857 + CCAGGUAGAGUUGCUCC 17 11783 BCL11A-9858 + GCAGCGCCCAAGUCUCC 17 11784 BCL11A-9859 - UACGGAGGAGGGUGUCC 17 11785 BCL11A-9860 - GUCUAAAAAACGAUUCC 17 11786 BCL11A-9861 + GCGUCUCCCGUCCUUCC 17 11787 BCL11A-9862 - CCCGGUCCCCUCUUUCC 17 11788 BCL11A-9863 + AGUUACAGCUCCGCAGC 17 11789 BCL11A-9864 + CCGGCACAAAAGGCAGC 17 11790 BCL11A-9865 - ACGGUCAAGUGUGCAGC 17 11791 BCL11A-9866 + GGGCAAGCGCGAGGAGC 17 11792 BCL11A-9620 - CGUGUGUGGGGGGGAGC 17 11793 BCL11A-9867 - AACCUGGGGGUGGGAGC 17 11794 BCL11A-9868 - CCCUGGCGUCCACACGC 17 11795 BCL11A-9869 - UUCCCGAGCGCAGCCGC 17 11796 BCL11A-9870 + CCGGGCUGGGGAAGCGC 17 11797 BCL11A-9871 + CGCGGACUCAGGAGCGC 17 11798 BCL11A-9872 - CUCUUUCCAGGCCGCGC 17 11799 BCL11A-9873 + CUUGACCGUGAGCGCGC 17 11800 BCL11A-9874 + GGAGAGGCAGGCGGCGC 17 11801 BCL11A-9875 + AGGCAGGCGGCGCAGGC 17 11802 BCL11A-9876 + GGGGACCGGGGAGAGGC 17 11803 BCL11A-9877 - GCCCUCCAAACUUAGGC 17 11804 BCL11A-9878 - AGGACGGGAGACGCGGC 17 11805 BCL11A-9879 - GCGAGCGCGGCGGCGGC 17 11806 BCL11A-9880 + AGGCUGCAGCCCCGGGC 17 11807 BCL11A-9881 + UGCAAAACUGGCGGGGC 17 11808 BCL11A-9882 + UAUUUUGCAAAACUGGC 17 11809 BCL11A-9883 + AAACACCCACCUCUGGC 17 11810 BCL11A-9884 + UAAGUUUGGAGGGCUGC 17 11811 BCL11A-9885 + ACAAAAGGCGGCAGUGC 17 11812 BCL11A-9886 - CCCGCUGCCUUUUGUGC 17 11813 BCL11A-9887 + CCCGACUCCGCGGACUC 17 11814 BCL11A-9888 + GGACAAACACCCACCUC 17 11815 BCL11A-9889 - GCCUUGGGGGCGCCCUC 17 11816 BCL11A-9890 - UUUGCUGUCCUCUCCUC 17 11817 BCL11A-9891 + AGCCCGCGGCUGCGCUC 17 11818 BCL11A-9892 - AGCGCAGCCGCGGGCUC 17 11819 BCL11A-9893 - CCUGAGUCCGCGGAGUC 17 11820 BCL11A-9894 + UUGGAGGGCUGCGGGUC 17 11821 BCL11A-9895 - GUACGGAGGAGGGUGUC 17 11822 BCL11A-9896 - GCUCAGCUCUCAACUUC 17 11823 BCL11A-9897 - CUUGGGCGCUGCCCUUC 17 11824 BCL11A-9898 - ACUGCCGCCUUUUGUUC 17 11825 BCL11A-9899 - AUUCCCGGGGAGAAAAG 17 11826 BCL11A-9900 - CCACAAUAGUGAGAAAG 17 11827 BCL11A-9901 + GGCGGAAAGGAGGAAAG 17 11828 BCL11A-9902 + CCGCGCGGCCUGGAAAG 17 11829 BCL11A-9903 - AGUGGCACUGUGGAAAG 17 11830 BCL11A-9904 + CGAAAAGAGAAAUAAAG 17 11831 BCL11A-9905 - GCGGCGGGGAGGGGAAG 17 11832 BCL11A-9906 + CCGCGUGUGGACGCCAG 17 11833 BCL11A-9907 - CCUUUUGUUCCGGCCAG 17 11834 BCL11A-9908 + AAGUUACAGCUCCGCAG 17 11835 BCL11A-9909 + GCCGGCACAAAAGGCAG 17 11836 BCL11A-9910 - CACGGUCAAGUGUGCAG 17 11837 BCL11A-9911 + GCGCGGCCUGGAAAGAG 17 11838 BCL11A-9912 - CCGCGGAGUCGGGAGAG 17 11839 BCL11A-9913 + GCUCCGCAGCGGGCGAG 17 11840 BCL11A-9914 + AAACUUUGCCCGAGGAG 17 11841 BCL11A-9915 - GUCCGCGGAGUCGGGAG 17 11842 BCL11A-9916 + AAGAGGGGACCGGGGAG 17 11843 BCL11A-9917 - GCGGCGGCGGCGGGGAG 17 11844 BCL11A-9918 + GCGGGGCGGGGGGGGAG 17 11845 BCL11A-9919 + CAUUUUCUUACGGUGAG 17 11846 BCL11A-9920 + GGGAGCGCACGGCAACG 17 11847 BCL11A-9642 + GCUCCCCCCCACACACG 17 11848 BCL11A-9921 - CCCCUGGCGUCCACACG 17 11849 BCL11A-9922 - GGGAAGGACGGGAGACG 17 11850 BCL11A-9923 - GAGGGGCCGCGGCGACG 17 11851 BCL11A-9924 + CUGGAAAGAGGGGACCG 17 11852 BCL11A-9925 - CGCGCUUCCCCAGCCCG 17 11853 BCL11A-9926 + UAAAAGCCCCGAGCCCG 17 11854 BCL11A-9927 + GCGCAGGCCGGGGCCCG 17 11855 BCL11A-9928 + UCGGGAAACUUUGCCCG 17 11856 BCL11A-9929 - CUAAAAAACGAUUCCCG 17 11857 BCL11A-9930 - UUUCCCGAGCGCAGCCG 17 11858 BCL11A-9931 - GGCGACGGGGAGAGCCG 17 11859 BCL11A-9932 + CGGACUCAGGAGCGCCG 17 11860 BCL11A-9933 + GGCUCUCCCCGUCGCCG 17 11861 BCL11A-9934 + GCAGGCGGCGCAGGCCG 17 11862 BCL11A-9935 - AGUCGGGAGAGGGGCCG 17 11863 BCL11A-9936 + CCCCUCUCCCGACUCCG 17 11864 BCL11A-9937 - CGGCGCUCCUGAGUCCG 17 11865 BCL11A-9938 + CCCGGGCUGGGGAAGCG 17 11866 BCL11A-9939 - CACGCGGGGAGCGAGCG 17 11867 BCL11A-9940 - CCUGGCGUCCACACGCG 17 11868 BCL11A-9941 + GUCUCCAGGAGCCCGCG 17 11869 BCL11A-9942 - CCUCUUUCCAGGCCGCG 17 11870 BCL11A-9943 + GCGGGAGGGCAAGCGCG 17 11871 BCL11A-9944 - CGAGCGCGGCGGCGGCG 17 11872 BCL11A-9945 + CAGCUCCGCAGCGGGCG 17 11873 BCL11A-9946 + GCAAAACUGGCGGGGCG 17 11874 BCL11A-9947 + AUUUUGCAAAACUGGCG 17 11875 BCL11A-9948 - GCGCAGCCGCGGGCUCG 17 11876 BCL11A-9949 + CUGGCCGGAACAAAAGG 17 11877 BCL11A-9950 + AUAAAGCGGCGGAAAGG 17 11878 BCL11A-9951 + GACCGGGGAGAGGCAGG 17 11879 BCL11A-9952 + GGAAAGGAGGAAAGAGG 17 11880 BCL11A-9953 - UUUGUUCCGGCCAGAGG 17 11881 BCL11A-9954 - GGGUGUGCGUACGGAGG 17 11882 BCL11A-9955 + CAGCGGGCGAGGGGAGG 17 11883 BCL11A-9956 - AGUGGGUGUGCGUACGG 17 11884 BCL11A-9957 + GGACUCAGGAGCGCCGG 17 11885 BCL11A-9958 + AAAGAGAAAUAAAGCGG 17 11886 BCL11A-9959 - GCGGGGAGCGAGCGCGG 17 11887 BCL11A-9960 - GGGAGCGAGCGCGGCGG 17 11888 BCL11A-9961 - AGCGAGCGCGGCGGCGG 17 11889 BCL11A-9962 + UGGGGAAGCGCGGGCGG 17 11890 BCL11A-9963 + CAAAACUGGCGGGGCGG 17 11891 BCL11A-9964 - AGCUGGUGGGGAAAGGG 17 11892 BCL11A-9965 - AAAAUGGGGGGGUAGGG 17 11893 BCL11A-9966 + AGCGAGAGUGCACCGGG 17 11894 BCL11A-9967 - GUCAAGUGUGCAGCGGG 17 11895 BCL11A-9968 + GGCUGGGGAAGCGCGGG 17 11896 BCL11A-9969 + AAAACUGGCGGGGCGGG 17 11897 BCL11A-9970 + CCGCAGCGGGCGAGGGG 17 11898 BCL11A-9971 - GCGCGGCGGCGGCGGGG 17 11899 BCL11A-9972 + AAACUGGCGGGGCGGGG 17 11900 BCL11A-9973 + UUGCAAAACUGGCGGGG 17 11901 BCL11A-9974 + AACUGGCGGGGCGGGGG 17 11902 BCL11A-9975 - ACAUGCAAACCUGGGGG 17 11903 BCL11A-9976 - ACCGUAAGAAAAUGGGG 17 11904 BCL11A-9548 - AGUCCGCGUGUGUGGGG 17 11905 BCL11A-9977 - CACCGUAAGAAAAUGGG 17 11906 BCL11A-9978 + GGGCGAGGGGAGGUGGG 17 11907 BCL11A-9668 - GAGUCCGCGUGUGUGGG 17 11908 BCL11A-9979 - UCACCGUAAGAAAAUGG 17 11909 BCL11A-9980 + UUAUUUUGCAAAACUGG 17 11910 BCL11A-9981 - CUCACAUGCAAACCUGG 17 11911 BCL11A-9982 - CUGGGGGUGGGAGCUGG 17 11912 BCL11A-9670 - AGAGUCCGCGUGUGUGG 17 11913 BCL11A-9983 - GCGGAGCUGUAACUUGG 17 11914 BCL11A-9984 - CCCUGGCUCGGCCUUGG 17 11915 BCL11A-9985 + AUCCAGCCUAAGUUUGG 17 11916 BCL11A-9986 - CUCACCGUAAGAAAAUG 17 11917 BCL11A-9987 - GUGAGAAAGUGGCACUG 17 11918 BCL11A-9988 - ACUCACAUGCAAACCUG 17 11919 BCL11A-9989 - CCUCCCCUCGCCCGCUG 17 11920 BCL11A-9990 + CUAAGUUUGGAGGGCUG 17 11921 BCL11A-9991 + GCUGCAGCCCCGGGCUG 17 11922 BCL11A-9992 + CGCUCGCUCCCCGCGUG 17 11923 BCL11A-9993 - GGGGGUGGGAGCUGGUG 17 11924 BCL11A-9678 - UUUAGAGUCCGCGUGUG 17 11925 BCL11A-9549 - UAGAGUCCGCGUGUGUG 17 11926 BCL11A-9994 + ACUUUCUCACUAUUGUG 17 11927 BCL11A-9995 + CCACUUUCUCACUAUUG 17 11928 BCL11A-9996 - UCCCUGGCUCGGCCUUG 17 11929 BCL11A-9997 - ACUCACCGUAAGAAAAU 17 11930 BCL11A-9998 - GCUGCGGAGCUGUAACU 17 11931 BCL11A-9999 - GCGGGCUCCUGGAGACU 17 11932 BCL11A-10000 - AACUCACAUGCAAACCU 17 11933 BCL11A-10001 - GGCCUUGGGGGCGCCCU 17 11934 BCL11A-10002 - GGUCCCUGGCUCGGCCU 17 11935 BCL11A-10003 - CUUUGCUGUCCUCUCCU 17 11936 BCL11A-10004 + GAGCCCGCGGCUGCGCU 17 11937 BCL11A-10005 + GGCUGCAGCCCCGGGCU 17 11938 BCL11A-10006 - GAGCGCAGCCGCGGGCU 17 11939 BCL11A-10007 - CGGCGGGGAGGGGAAGU 17 11940 BCL11A-10008 - UCCUGAGUCCGCGGAGU 17 11941 BCL11A-10009 + AUUUUCUUACGGUGAGU 17 11942 BLC11A-10010 - GCGACGGGGAGAGCCGU 17 11943 BCL11A-10011 - UUGUUCCGGCCAGAGGU 17 11944 BCL11A-10012 + AGCGGGCGAGGGGAGGU 17 11945 BCL11A-10013 - UAAGAAAAUGGGGGGGU 17 11946 BCL11A-10014 - CAUGCAAACCUGGGGGU 17 11947 BCL11A-10015 - UGGGGGUGGGAGCUGGU 17 11948 BCL11A-9687 - UUAGAGUCCGCGUGUGU 17 11949 BCL11A-10016 + CACUUUCUCACUAUUGU 17 11950 BCL11A-10017 - CGCAGCCCUCCAAACUU 17 11951 BCL11A-10018 - GGCUCAGCUCUCAACUU 17 11952 BCL11A-10019 - CGGGCUCCUGGAGACUU 17 11953 BCL11A-10020 - GCUCGGGGCUUUUACUU 17 11954 BCL11A-10021 - GUCCCUGGCUCGGCCUU 17 11955 BCL11A-10022 + GGAAUCCAGCCUAAGUU 17 11956 BCL11A-10023 - GAGGUGAGACUGGCUUU 17 11957 BCL11A-10024 - UCCCACUCACCGUAAGAAAA 20 11958 BLC11A-10025 + CCACCUCUGGCCGGAACAAA 20 11959 BCL11A-10026 + GCGCGAGGAGCCGGCACAAA 20 11960 BCL11A-10027 - CUUUAUUUCUCUUUUCGAAA 20 11961 BCL11A-10028 - GGUGGGAGCUGGUGGGGAAA 20 11962 BCL11A-10029 - AGAAAGUGGCACUGUGGAAA 20 11963 BCL11A-10030 + GGAGGGCUGCGGGUCCGGAA 20 11964 BCL11A-10031 + AGAGAAAUAAAGCGGCGGAA 20 11965 BCL11A-10032 - GGGUGGGAGCUGGUGGGGAA 20 11966 BCL11A-10033 - GAGAAAGUGGCACUGUGGAA 20 11967 BCL11A-10034 + GGGGCCCGAGGGCGCCCCCA 20 11968 BCL11A-10035 + UCCCGUCCUUCCCGGUCCCA 20 11969 BCL11A-10036 + GCGCCCCCAAGGCCGAGCCA 20 11970 BCL11A-10037 + CUCCCCGCGUGUGGACGCCA 20 11971 BCL11A-9701 - CGCGUGUGUGGGGGGGAGCA 20 11972 BCL11A-10038 + GGGAGGUGGGAGGGAGCGCA 20 11973 BCL11A-10039 - UUUGGACACCAGCGCGCUCA 20 11974 BCL11A-10040 + GCCCGCGCGGCCUGGAAAGA 20 11975 BCL11A-10041 - GAGUCCGCGGAGUCGGGAGA 20 11976 BCL11A-10042 + CGGCGCAGGCCGGGGCCCGA 20 11977 BCL11A-10043 - CGGGAGAGGGGCCGCGGCGA 20 11978 BCL11A-10044 + UACAGCUCCGCAGCGGGCGA 20 11979 BCL11A-10045 - AGCCGUGGGACCGGGAAGGA 20 11980 BCL11A-10046 - GUGGGUGUGCGUACGGAGGA 20 11981 BCL11A-10047 + UGGAGGGCUGCGGGUCCGGA 20 11982 BCL11A-10048 + GCUGGGGAAGCGCGGGCGGA 20 11983 BCL11A-10049 - AGAAAAUGGGGGGGUAGGGA 20 11984 BCL11A-10050 - GGAGAGCCGUGGGACCGGGA 20 11985 BCL11A-10051 - GAGCGCGGCGGCGGCGGGGA 20 11986 BCL11A-10052 + GCGGGCGAGGGGAGGUGGGA 20 11987 BCL11A-10053 + GAAUCCAGCCUAAGUUUGGA 20 11988 BCL11A-10054 - CAAAAUAAUGAACAAUGCUA 20 11989 BCL11A-10055 - AGGGGAAGUGGGUGUGCGUA 20 11990 BCL11A-10056 - CGUAAGAAAAUGGGGGGGUA 20 11991 BCL11A-10057 + CCUACCCCCCCAUUUUCUUA 20 11992 BCL11A-10058 + UGUUCAUUAUUUUGCAAAAC 20 11993 BCL11A-10059 + AAAAUAGAGCGAGAGUGCAC 20 11994 BCL11A-10060 - GGGGAGAAAAGAGGUGAGAC 20 11995 BCL11A-10061 - GGGAGAGGGGCCGCGGCGAC 20 11996 BCL11A-10062 - GCCGUGGGACCGGGAAGGAC 20 11997 BCL11A-10063 + CCCAAGGCCGAGCCAGGGAC 20 11998 BCL11A-10064 + GCGGCCUGGAAAGAGGGGAC 20 11999 BCL11A-10065 - GACGGGGAGAGCCGUGGGAC 20 12000 BCL11A-10066 - GAACAACUCACAUGCAAACC 20 12001 BCL11A-10067 + AAAUAGAGCGAGAGUGCACC 20 12002 BCL11A-10068 + CCAAGGCCGAGCCAGGGACC 20 12003 BCL11A-10069 + CGGCCUGGAAAGAGGGGACC 20 12004 BCL11A-10070 - ACGGGGAGAGCCGUGGGACC 20 12005 BCL11A-10071 - UGUCCGGGAGCAACUCUACC 20 12006 BCL11A-10072 + CCCCACCAGCUCCCACCCCC 20 12007 BCL11A-10073 + CACCGGGAGGCUGCAGCCCC 20 12008 BCL11A-10074 - GGGGCUUUUACUUCGGCCCC 20 12009 BCL11A-10075 - GCACUGUGGAAAGGGGCCCC 20 12010 BCL11A-10076 + GUCUCACCUCUUUUCUCCCC 20 12011 BCL11A-10077 - CGCCCGCGCUUCCCCAGCCC 20 12012 BCL11A-10078 + GCACCGGGAGGCUGCAGCCC 20 12013 BCL11A-10079 - UUGGGGGCGCCCUCGGGCCC 20 12014 BCL11A-10080 - CUGCGCCGCCUGCCUCUCCC 20 12015 BCL11A-10081 + AGUCUCACCUCUUUUCUCCC 20 12016 BCL11A-10082 - AAGUCUAAAAAACGAUUCCC 20 12017 BCL11A-10083 + AGCGCGGGCGGAGGGAAGCC 20 12018 BCL11A-10084 - CCGCCCGCGCUUCCCCAGCC 20 12019 BCL11A-10085 + GGCGCCCCCAAGGCCGAGCC 20 12020 BCL11A-10086 + GCUCCCCGCGUGUGGACGCC 20 12021 BCL11A-10087 + UCCGCGGACUCAGGAGCGCC 20 12022 BCL11A-10088 + AGAGGCAGGCGGCGCAGGCC 20 12023 BCL11A-10089 + CUCCAGGAGCCCGCGCGGCC 20 12024 BCL11A-10090 - AGCCCGGGGCUGCAGCCUCC 20 12025 BCL11A-10091 - UUCCAGGCCGCGCGGGCUCC 20 12026 BCL11A-10092 + AAGCCAGGUAGAGUUGCUCC 20 12027 BCL11A-10093 + AGGGCAGCGCCCAAGUCUCC 20 12028 BCL11A-10094 - GCGUACGGAGGAGGGUGUCC 20 12029 BCL11A-10095 - CAAGUCUAAAAAACGAUUCC 20 12030 BCL11A-10096 + GCCGCGUCUCCCGUCCUUCC 20 12031 BCL11A-10097 - CUCCCCGGUCCCCUCUUUCC 20 12032 BCL11A-10098 + CCAAGUUACAGCUCCGCAGC 20 12033 BCL11A-10099 + GAGCCGGCACAAAAGGCAGC 20 12034 BCL11A-10100 - CUCACGGUCAAGUGUGCAGC 20 12035 BCL11A-10101 + GGAGGGCAAGCGCGAGGAGC 20 12036 BCL11A-9563 - CCGCGUGUGUGGGGGGGAGC 20 12037 BCL11A-10102 - GCAAACCUGGGGGUGGGAGC 20 12038 BCL11A-10103 - GGCCCCUGGCGUCCACACGC 20 12039 BCL11A-10104 - AGUUUCCCGAGCGCAGCCGC 20 12040 BCL11A-10105 + GCCCCGGGCUGGGGAAGCGC 20 12041 BCL11A-10106 + CUCCGCGGACUCAGGAGCGC 20 12042 BCL11A-10107 - CCCCUCUUUCCAGGCCGCGC 20 12043 BCL11A-10108 + ACACUUGACCGUGAGCGCGC 20 12044 BCL11A-10109 + CGGGGAGAGGCAGGCGGCGC 20 12045 BCL11A-10110 + GAGAGGCAGGCGGCGCAGGC 20 12046 BCL11A-10111 + AGAGGGGACCGGGGAGAGGC 20 12047 BCL11A-10112 - GCAGCCCUCCAAACUUAGGC 20 12048 BCL11A-10113 - GGAAGGACGGGAGACGCGGC 20 12049 BCL11A-10114 - GGAGCGAGCGCGGCGGCGGC 20 12050 BCL11A-10115 + GGGAGGCUGCAGCCCCGGGC 20 12051 BCL11A-10116 + UUUUGCAAAACUGGCGGGGC 20 12052 BCL11A-10117 + CAUUAUUUUGCAAAACUGGC 20 12053 BCL11A-10118 + GACAAACACCCACCUCUGGC 20 12054 BCL11A-10119 + GCCUAAGUUUGGAGGGCUGC 20 12055 BCL11A-10120 + GGAACAAAAGGCGGCAGUGC 20 12056 BCL11A-10121 - UGUCCCGCUGCCUUUUGUGC 20 12057 BCL11A-10122 + UCUCCCGACUCCGCGGACUC 20 12058 BCL11A-10123 + GCGGGACAAACACCCACCUC 20 12059 BCL11A-10124 - UCGGCCUUGGGGGCGCCCUC 20 12060 BCL11A-10125 - UUCUUUGCUGUCCUCUCCUC 20 12061 BCL11A-10126 + CCGAGCCCGCGGCUGCGCUC 20 12062 BCL11A-10127 - CCGAGCGCAGCCGCGGGCUC 20 12063 BCL11A-10128 - GCUCCUGAGUCCGCGGAGUC 20 12064 BCL11A-10129 + AGUUUGGAGGGCUGCGGGUC 20 12065 BCL11A-10130 - UGCGUACGGAGGAGGGUGUC 20 12066 BCL11A-10131 - GAGGCUCAGCUCUCAACUUC 20 12067 BCL11A-10132 - AGACUUGGGCGCUGCCCUUC 20 12068 BCL11A-10133 - GGCACUGCCGCCUUUUGUUC 20 12069 BCL11A-10134 - ACGAUUCCCGGGGAGAAAAG 20 12070 BCL11A-10135 - UCCCCACAAUAGUGAGAAAG 20 12071 BCL11A-10136 + AGCGGCGGAAAGGAGGAAAG 20 12072 BCL11A-10137 + AGCCCGCGCGGCCUGGAAAG 20 12073 BCL11A-10138 - GAAAGUGGCACUGUGGAAAG 20 12074 BCL11A-10139 + UUUCGAAAAGAGAAAUAAAG 20 12075 BCL11A-10140 - GCGGCGGCGGGGAGGGGAAG 20 12076 BCL11A-10141 + UCCCCGCGUGUGGACGCCAG 20 12077 BCL11A-10142 - CCGCCUUUUGUUCCGGCCAG 20 12078 BCL11A-10143 + UCCAAGUUACAGCUCCGCAG 20 12079 BCL11A-10144 + GGAGCCGGCACAAAAGGCAG 20 12080 BCL11A-10145 - GCUCACGGUCAAGUGUGCAG 20 12081 BCL11A-10146 + CCCGCGCGGCCUGGAAAGAG 20 12082 BCL11A-10147 - AGUCCGCGGAGUCGGGAGAG 20 12083 BCL11A-10148 + ACAGCUCCGCAGCGGGCGAG 20 12084 BCL11A-10149 + GGGAAACUUUGCCCGAGGAG 20 12085 BCL11A-10150 - UGAGUCCGCGGAGUCGGGAG 20 12086 BCL11A-10151 + GGAAAGAGGGGACCGGGGAG 20 12087 BCL11A-10152 - AGCGCGGCGGCGGCGGGGAG 20 12088 BCL11A-10153 + CUGGCGGGGCGGGGGGGGAG 20 12089 BLC11A-10154 + CCCCAUUUUCUUACGGUGAG 20 12090 BCL11A-10155 + GGAGGGAGCGCACGGCAACG 20 12091 BCL11A-9741 + CCUGCUCCCCCCCACACACG 20 12092 BCL11A-10156 - CGGCCCCUGGCGUCCACACG 20 12093 BCL11A-10157 - ACCGGGAAGGACGGGAGACG 20 12094 BCL11A-10158 - GGAGAGGGGCCGCGGCGACG 20 12095 BCL11A-10159 + GGCCUGGAAAGAGGGGACCG 20 12096 BCL11A-10160 - GCCCGCGCUUCCCCAGCCCG 20 12097 BCL11A-10161 + AAGUAAAAGCCCCGAGCCCG 20 12098 BCL11A-10162 + GCGGCGCAGGCCGGGGCCCG 20 12099 BCL11A-10163 + CGCUCGGGAAACUUUGCCCG 20 12100 BCL11A-10164 - AGUCUAAAAAACGAUUCCCG 20 12101 BCL11A-10165 - AAGUUUCCCGAGCGCAGCCG 20 12102 BCL11A-10166 - CGCGGCGACGGGGAGAGCCG 20 12103 BCL11A-10167 + CCGCGGACUCAGGAGCGCCG 20 12104 BCL11A-10168 + CACGGCUCUCCCCGUCGCCG 20 12105 BCL11A-10169 + GAGGCAGGCGGCGCAGGCCG 20 12106 BCL11A-10170 - CGGAGUCGGGAGAGGGGCCG 20 12107 BCL11A-10171 + CGGCCCCUCUCCCGACUCCG 20 12108 BCL11A-10172 - CCCCGGCGCUCCUGAGUCCG 20 12109 BCL11A-10173 + AGCCCCGGGCUGGGGAAGCG 20 12110 BCL11A-10174 - CCACACGCGGGGAGCGAGCG 20 12111 BCL11A-10175 - GCCCCUGGCGUCCACACGCG 20 12112 BCL11A-10176 + CAAGUCUCCAGGAGCCCGCG 20 12113 BCL11A-10177 - UCCCCUCUUUCCAGGCCGCG 20 12114 BCL11A-10178 + GGCGCGGGAGGGCAAGCGCG 20 12115 BCL11A-10179 - GAGCGAGCGCGGCGGCGGCG 20 12116 BCL11A-10180 + UUACAGCUCCGCAGCGGGCG 20 12117 BCL11A-10181 + UUUGCAAAACUGGCGGGGCG 20 12118 BCL11A-10182 + AUUAUUUUGCAAAACUGGCG 20 12119 BCL11A-10183 - CGAGCGCAGCCGCGGGCUCG 20 12120 BCL11A-10184 + CCUCUGGCCGGAACAAAAGG 20 12121 BCL11A-10185 + GAAAUAAAGCGGCGGAAAGG 20 12122 BCL11A-10186 + GGGGACCGGGGAGAGGCAGG 20 12123 BCL11A-10187 + GGCGGAAAGGAGGAAAGAGG 20 12124 BCL11A-10188 - CCUUUUGUUCCGGCCAGAGG 20 12125 BCL11A-10189 - AGUGGGUGUGCGUACGGAGG 20 12126 BCL11A-10190 + CCGCAGCGGGCGAGGGGAGG 20 12127 BCL11A-10191 - GGAAGUGGGUGUGCGUACGG 20 12128 BCL11A-10192 + CGCGGACUCAGGAGCGCCGG 20 12129 BCL11A-10193 + CGAAAAGAGAAAUAAAGCGG 20 12130 BCL11A-10194 - CACGCGGGGAGCGAGCGCGG 20 12131 BLC11A-10195 - GCGGGGAGCGAGCGCGGCGG 20 12132 BCL11A-10196 - GGGAGCGAGCGCGGCGGCGG 20 12133 BCL11A-10197 + GGCUGGGGAAGCGCGGGCGG 20 12134 BCL11A-10198 + UUGCAAAACUGGCGGGGCGG 20 12135 BCL11A-10199 - GGGAGCUGGUGGGGAAAGGG 20 12136 BCL11A-10200 - AAGAAAAUGGGGGGGUAGGG 20 12137 BCL11A-10201 + UAGAGCGAGAGUGCACCGGG 20 12138 BCL11A-10202 - ACGGUCAAGUGUGCAGCGGG 20 12139 BCL11A-10203 + CCGGGCUGGGGAAGCGCGGG 20 12140 BCL11A-10204 + UGCAAAACUGGCGGGGCGGG 20 12141 BCL11A-10205 + GCUCCGCAGCGGGCGAGGGG 20 12142 BCL11A-10206 - CGAGCGCGGCGGCGGCGGGG 20 12143 BCL11A-10207 + GCAAAACUGGCGGGGCGGGG 20 12144 BCL11A-10208 + AUUUUGCAAAACUGGCGGGG 20 12145 BCL11A-10209 + CAAAACUGGCGGGGCGGGGG 20 12146 BCL11A-10210 - CUCACAUGCAAACCUGGGGG 20 12147 BCL11A-10211 - CUCACCGUAAGAAAAUGGGG 20 12148 BCL11A-9577 - UAGAGUCCGCGUGUGUGGGG 20 12149 BCL11A-10212 - ACUCACCGUAAGAAAAUGGG 20 12150 BCL11A-10213 + AGCGGGCGAGGGGAGGUGGG 20 12151 BCL11A-9769 - UUAGAGUCCGCGUGUGUGGG 20 12152 BCL11A-10214 - CACUCACCGUAAGAAAAUGG 20 12153 BCL11A-10215 + UCAUUAUUUUGCAAAACUGG 20 12154 BCL11A-10216 - CAACUCACAUGCAAACCUGG 20 12155 BCL11A-10217 - AACCUGGGGGUGGGAGCUGG 20 12156 BCL11A-9578 - UUUAGAGUCCGCGUGUGUGG 20 12157 BCL11A-10218 - GCUGCGGAGCUGUAACUUGG 20 12158 BCL11A-10219 - GGUCCCUGGCUCGGCCUUGG 20 12159 BCL11A-10220 + GGAAUCCAGCCUAAGUUUGG 20 12160 BCL11A-10221 - CCACUCACCGUAAGAAAAUG 20 12161 BCL11A-10222 - AUAGUGAGAAAGUGGCACUG 20 12162 BCL11A-10223 - ACAACUCACAUGCAAACCUG 20 12163 BCL11A-10224 - CCACCUCCCCUCGCCCGCUG 20 12164 BCL11A-10225 + AGCCUAAGUUUGGAGGGCUG 20 12165 BCL11A-10226 + GAGGCUGCAGCCCCGGGCUG 20 12166 BCL11A-10227 + CCGCGCUCGCUCCCCGCGUG 20 12167 BCL11A-10228 - CCUGGGGGUGGGAGCUGGUG 20 12168 BCL11A-9581 - CAUUUUAGAGUCCGCGUGUG 20 12169 BCL11A-9776 - UUUUAGAGUCCGCGUGUGUG 20 12170 BCL11A-10229 + GCCACUUUCUCACUAUUGUG 20 12171 BCL11A-10230 + GUGCCACUUUCUCACUAUUG 20 12172 BCL11A-10231 - CGGUCCCUGGCUCGGCCUUG 20 12173 BCL11A-10232 - CCCACUCACCGUAAGAAAAU 20 12174 BCL11A-10233 - CCCGCUGCGGAGCUGUAACU 20 12175 BCL11A-10234 - CGCGCGGGCUCCUGGAGACU 20 12176 BCL11A-10235 - AACAACUCACAUGCAAACCU 20 12177 BCL11A-10236 - CUCGGCCUUGGGGGCGCCCU 20 12178 BCL11A-10237 - CCCGGUCCCUGGCUCGGCCU 20 12179 BCL11A-10238 - UUUCUUUGCUGUCCUCUCCU 20 12180 BCL11A-10239 + CCCGAGCCCGCGGCUGCGCU 20 12181 BCL11A-10240 + GGAGGCUGCAGCCCCGGGCU 20 12182 BCL11A-10241 - CCCGAGCGCAGCCGCGGGCU 20 12183 BCL11A-10242 - CGGCGGCGGGGAGGGGAAGU 20 12184 BCL11A-10243 - CGCUCCUGAGUCCGCGGAGU 20 12185 BCL11A-10244 + CCCAUUUUCUUACGGUGAGU 20 12186 BCL11A-10245 - GCGGCGACGGGGAGAGCCGU 20 12187 BCL11A-10246 - CUUUUGUUCCGGCCAGAGGU 20 12188 BCL11A-10247 + CGCAGCGGGCGAGGGGAGGU 20 12189 BCL11A-10248 - CCGUAAGAAAAUGGGGGGGU 20 12190 BCL11A-10249 - UCACAUGCAAACCUGGGGGU 20 12191 BCL11A-10250 - ACCUGGGGGUGGGAGCUGGU 20 12192 BCL11A-9586 - AUUUUAGAGUCCGCGUGUGU 20 12193 BCL11A-10251 + UGCCACUUUCUCACUAUUGU 20 12194 BCL11A-10252 - ACCCGCAGCCCUCCAAACUU 20 12195 BCL11A-10253 - GGAGGCUCAGCUCUCAACUU 20 12196 BCL11A-10254 - GCGCGGGCUCCUGGAGACUU 20 12197 BCL11A-10255 - CGGGCUCGGGGCUUUUACUU 20 12198 BCL11A-10256 - CCGGUCCCUGGCUCGGCCUU 20 12199 BCL11A-10257 + CGCGGAAUCCAGCCUAAGUU 20 12200 BCL11A-10258 - AAAGAGGUGAGACUGGCUUU 20 12201

Table 19A provides exemplary targeting domains for knocking down the BCL11A gene selected according to the first tier parameters. The targeting domains bind within 500 bp (e.g., upstream or downstream) of a transcription start site (TSS) and have a high level of orthogonality, and the PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL11A protein function, or the level of BCL11A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 19A 1st Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-10259 + GGCGUGGCCGGGAGAGAAGAA 21 12202 BCL11A-10260 + UGGCGUGGCCGGGAGAGAAGAA 22 12203 BCL11A-10261 + GUGGCGUGGCCGGGAGAGAAGAA 23 12204 BCL11A-10262 + GGUGGCGUGGCCGGGAGAGAAGAA 24 12205 BCL11A-10263 + CACGGCAAUGGUUCCAGA 18 12206 BCL11A-10264 + ACACGGCAAUGGUUCCAGA 19 12207 BCL11A-9557 + UACACGGCAAUGGUUCCAGA 20 12208 BCL11A-10265 + AUACACGGCAAUGGUUCCAGA 21 12209 BCL11A-10266 + CAUACACGGCAAUGGUUCCAGA 22 12210 BCL11A-10267 + GCAUACACGGCAAUGGUUCCAGA 23 12211 BCL11A-10268 + UGCAUACACGGCAAUGGUUCCAGA 24 12212 BCL11A-6258 + UUAUUGGGUUACUUACGC 18 12213 BCL11A-6259 + AUUAUUGGGUUACUUACGC 19 12214 BCL11A-6260 + UAUUAUUGGGUUACUUACGC 20 12215 BCL11A-6261 + CUAUUAUUGGGUUACUUACGC 21 12216 BCL11A-6262 + ACUAUUAUUGGGUUACUUACGC 22 12217 BCL11A-6263 + UACUAUUAUUGGGUUACUUACGC 23 12218 BCL11A-6264 + UUACUAUUAUUGGGUUACUUACGC 24 12219 BCL11A-10269 + GGGAGAGAAGAAAGGGGUGGC 21 12220 BCL11A-10270 + CGGGAGAGAAGAAAGGGGUGGC 22 12221 BCL11A-10271 + CCGGGAGAGAAGAAAGGGGUGGC 23 12222 BCL11A-10272 + GCCGGGAGAGAAGAAAGGGGUGGC 24 12223 BCL11A-6265 + UCCCGUUUGCUUAAGUGC 18 12224 BCL11A-6266 + UUCCCGUUUGCUUAAGUGC 19 12225 BCL11A-5352 + AUUCCCGUUUGCUUAAGUGC 20 12226 BCL11A-6267 + AAUUCCCGUUUGCUUAAGUGC 21 12227 BCL11A-6268 + GAAUUCCCGUUUGCUUAAGUGC 22 12228 BCL11A-6269 + AGAAUUCCCGUUUGCUUAAGUGC 23 12229 BCL11A-6270 + GAGAAUUCCCGUUUGCUUAAGUGC 24 12230 BCL11A-10273 + CCUGCGAACUUGAACGUC 18 12231 BCL11A-10274 + CCCUGCGAACUUGAACGUC 19 12232 BCL11A-9570 + UCCCUGCGAACUUGAACGUC 20 12233 BCL11A-10275 + GUCCCUGCGAACUUGAACGUC 21 12234 BCL11A-10276 + CGUCCCUGCGAACUUGAACGUC 22 12235 BCL11A-10277 + ACGUCCCUGCGAACUUGAACGUC 23 12236 BCL11A-10278 + GACGUCCCUGCGAACUUGAACGUC 24 12237 BCL11A-10279 + UACAAAGAUGGCGCAGGGAAG 21 12238 BCL11A-10280 + AUACAAAGAUGGCGCAGGGAAG 22 12239 BCL11A-10281 + AAUACAAAGAUGGCGCAGGGAAG 23 12240 BCL11A-10282 + UAAUACAAAGAUGGCGCAGGGAAG 24 12241 BCL11A-10283 + CGGUUCACAUCGGGAGAG 18 12242 BCL11A-10284 + UCGGUUCACAUCGGGAGAG 19 12243 BCL11A-10285 + CUCGGUUCACAUCGGGAGAG 20 12244 BCL11A-10286 + GCUCGGUUCACAUCGGGAGAG 21 12245 BCL11A-10287 + GGCUCGGUUCACAUCGGGAGAG 22 12246 BCL11A-10288 + CGGCUCGGUUCACAUCGGGAGAG 23 12247 BCL11A-10289 + ACGGCUCGGUUCACAUCGGGAGAG 24 12248 BCL11A-10290 + AAUGGUUCCAGAUGGGAU 18 12249 BCL11A-10291 + CAAUGGUUCCAGAUGGGAU 19 12250 BCL11A-10292 + GCAAUGGUUCCAGAUGGGAU 20 12251 BCL11A-10293 + GGCAAUGGUUCCAGAUGGGAU 21 12252 BCL11A-10294 + CGGCAAUGGUUCCAGAUGGGAU 22 12253 BCL11A-10295 + ACGGCAAUGGUUCCAGAUGGGAU 23 12254 BCL11A-10296 + CACGGCAAUGGUUCCAGAUGGGAU 24 12255 BCL11A-10297 + AACUUGAACGUCAGGAGU 18 12256 BCL11A-10298 + GAACUUGAACGUCAGGAGU 19 12257 BCL11A-10299 + CGAACUUGAACGUCAGGAGU 20 12258 BCL11A-10300 + GCGAACUUGAACGUCAGGAGU 21 12259 BCL11A-10301 + UGCGAACUUGAACGUCAGGAGU 22 12260 BCL11A-10302 + CUGCGAACUUGAACGUCAGGAGU 23 12261 BCL11A-10303 + CCUGCGAACUUGAACGUCAGGAGU 24 12262 BCL11A-6304 - AACCCCAGCACUUAAGCAAAC 21 12263 BCL11A-6305 - AAACCCCAGCACUUAAGCAAAC 22 12264 BCL11A-6306 - CAAACCCCAGCACUUAAGCAAAC 23 12265 BCL11A-6307 - GCAAACCCCAGCACUUAAGCAAAC 24 12266 BCL11A-10304 - AAGCAAAAGCGAGGGGGAGAG 21 12267 BCL11A-10305 - GAAGCAAAAGCGAGGGGGAGAG 22 12268 BCL11A-10306 - AGAAGCAAAAGCGAGGGGGAGAG 23 12269 BCL11A-10307 - UAGAAGCAAAAGCGAGGGGGAGAG 24 12270

Table 19B provides exemplary targeting domains for knocking down the BCL11A gene selected according to the second tier parameters. The targeting domains bind within 500 bp (e.g., upstream or downstream) of a transcription start site (TSS), and PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL11A protein function, or the level of BCL11A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 19B 2nd Tier Target DNA Site SEQ gRNA Name Strand Targeting Domain Length ID NO: BCL11A-10308 + GUGGCCGGGAGAGAAGAA 18 12271 BCL11A-10309 + CGUGGCCGGGAGAGAAGAA 19 12272 BCL11A-9697 + GCGUGGCCGGGAGAGAAGAA 20 12273 BCL11A-10310 + GUGGCAGGGGUGGGAGGA 18 12274 BCL11A-10311 + GGUGGCAGGGGUGGGAGGA 19 12275 BCL11A-10312 + GGGUGGCAGGGGUGGGAGGA 20 12276 BCL11A-10313 + GGGGUGGCAGGGGUGGGAGGA 21 12277 BCL11A-10314 + AGGGGUGGCAGGGGUGGGAGGA 22 12278 BCL11A-10315 + AAGGGGUGGCAGGGGUGGGAGGA 23 12279 BCL11A-10316 + AAAGGGGUGGCAGGGGUGGGAGGA 24 12280 BCL11A-10317 + UAAUUAUUAUUACUAUUA 18 12281 BCL11A-10318 + AUAAUUAUUAUUACUAUUA 19 12282 BCL11A-10319 + AAUAAUUAUUAUUACUAUUA 20 12283 BCL11A-10320 + UAAUAAUUAUUAUUACUAUUA 21 12284 BCL11A-10321 + UUAAUAAUUAUUAUUACUAUUA 22 12285 BCL11A-10322 + AUUAAUAAUUAUUAUUACUAUUA 23 12286 BCL11A-10323 + UAUUAAUAAUUAUUAUUACUAUUA 24 12287 BCL11A-10324 + AGAGAAGAAAGGGGUGGC 18 12288 BCL11A-10325 + GAGAGAAGAAAGGGGUGGC 19 12289 BCL11A-9726 + GGAGAGAAGAAAGGGGUGGC 20 12290 BCL11A-10326 + AAAGAUGGCGCAGGGAAG 18 12291 BCL11A-10327 + CAAAGAUGGCGCAGGGAAG 19 12292 BCL11A-10328 + ACAAAGAUGGCGCAGGGAAG 20 12293 BCL11A-6350 - CCCAGCACUUAAGCAAAC 18 12294 BCL11A-6351 - CCCCAGCACUUAAGCAAAC 19 12295 BCL11A-5458 - ACCCCAGCACUUAAGCAAAC 20 12296 BCL11A-10329 - UUCACGAGAAAAACCUCC 18 12297 BCL11A-10330 - UUUCACGAGAAAAACCUCC 19 12298 BCL11A-10331 - UUUUCACGAGAAAAACCUCC 20 12299 BCL11A-10332 - UUUUUCACGAGAAAAACCUCC 21 12300 BCL11A-10333 - AUUUUUCACGAGAAAAACCUCC 22 12301 BCL11A-10334 - AAUUUUUCACGAGAAAAACCUCC 23 12302 BCL11A-10335 - AAAUUUUUCACGAGAAAAACCUCC 24 12303 BCL11A-10336 - UGAUGAAGAUAUUUUCUC 18 12304 BCL11A-10337 - CUGAUGAAGAUAUUUUCUC 19 12305 BCL11A-9731 - ACUGAUGAAGAUAUUUUCUC 20 12306 BCL11A-10338 - CACUGAUGAAGAUAUUUUCUC 21 12307 BCL11A-10339 - GCACUGAUGAAGAUAUUUUCUC 22 12308 BCL11A-10340 - GGCACUGAUGAAGAUAUUUUCUC 23 12309 BCL11A-10341 - AGGCACUGAUGAAGAUAUUUUCUC 24 12310 BCL11A-10342 - CAAAAGCGAGGGGGAGAG 18 12311 BCL11A-10343 - GCAAAAGCGAGGGGGAGAG 19 12312 BCL11A-4583 - AGCAAAAGCGAGGGGGAGAG 20 12313 BCL11A-10344 - UAUUAUUUCUAAUUUAUU 18 12314 BCL11A-10345 - GUAUUAUUUCUAAUUUAUU 19 12315 BCL11A-10346 - UGUAUUAUUUCUAAUUUAUU 20 12316 BCL11A-10347 - UUGUAUUAUUUCUAAUUUAUU 21 12317 BCL11A-10348 - UUUGUAUUAUUUCUAAUUUAUU 22 12318 BCL11A-10349 - CUUUGUAUUAUUUCUAAUUUAUU 23 12319 BCL11A-10350 - UCUUUGUAUUAUUUCUAAUUUAUU 24 12320 BCL11A-10351 - UUGAAUAAUCUUUCAUUU 18 12321 BCL11A-10352 - UUUGAAUAAUCUUUCAUUU 19 12322 BCL11A-10353 - UUUUGAAUAAUCUUUCAUUU 20 12323 BCL11A-10354 - UUUUUGAAUAAUCUUUCAUUU 21 12324 BCL11A-10355 - UUUUUUGAAUAAUCUUUCAUUU 22 12325 BCL11A-10356 - CUUUUUUGAAUAAUCUUUCAUUU 23 12326 BCL11A-10357 - UCUUUUUUGAAUAAUCUUUCAUUU 24 12327

Table 19C provides exemplary targeting domains for knocking down the BCL11A gene selected according to the third tier parameters. The targeting domains bind within 500 bp (e.g., upstream or downstream) of a transcription start site (TSS), and the PAM is NNGRRV. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL11A protein function, or the level of BCL11A protein). One or more gRNA may be used

TABLE 19C 3rd Tier Target DNA Site SEQ gRNA Name Strand Targeting Domain Length ID NO: BCL11A-10358 + AAAAAAAAAAAAAAAAAA 18 12328 BCL11A-10359 + AAAAAAAAAAAAAAAAAAA 19 12329 BCL11A-4899 + AAAAAAAAAAAAAAAAAAAA 20 12330 BCL11A-10360 + AAAAAAAAAAAAAAAAAAAAA 21 12331 BCL11A-10361 + AAAAAAAAAAAAAAAAAAAAAA 22 12332 BCL11A-10362 + AAAAAAAAAAAAAAAAAAAAAAA 23 12333 BCL11A-10363 + AAAAAAAAAAAAAAAAAAAAAAAA 24 12334 BCL11A-10364 + CAGGGGCUGGACAUGAAA 18 12335 BCL11A-10365 + UCAGGGGCUGGACAUGAAA 19 12336 BCL11A-10366 + AUCAGGGGCUGGACAUGAAA 20 12337 BCL11A-10367 + CAUCAGGGGCUGGACAUGAAA 21 12338 BCL11A-10368 + ACAUCAGGGGCUGGACAUGAAA 22 12339 BCL11A-10369 + CACAUCAGGGGCUGGACAUGAAA 23 12340 BCL11A-10370 + ACACAUCAGGGGCUGGACAUGAAA 24 12341 BCL11A-10371 + ACACACGCGGACUCUAAA 18 12342 BCL11A-10372 + CACACACGCGGACUCUAAA 19 12343 BCL11A-10373 + CCACACACGCGGACUCUAAA 20 12344 BCL11A-10374 + CCCACACACGCGGACUCUAAA 21 12345 BCL11A-10375 + CCCCACACACGCGGACUCUAAA 22 12346 BCL11A-10376 + CCCCCACACACGCGGACUCUAAA 23 12347 BCL11A-10377 + CCCCCCACACACGCGGACUCUAAA 24 12348 BCL11A-10378 + AGAGGGAGAGAGAGAGAA 18 12349 BCL11A-10379 + AAGAGGGAGAGAGAGAGAA 19 12350 BCL11A-4921 + AAAGAGGGAGAGAGAGAGAA 20 12351 BCL11A-10380 + AAAAGAGGGAGAGAGAGAGAA 21 12352 BCL11A-10381 + AAAAAGAGGGAGAGAGAGAGAA 22 12353 BCL11A-10382 + AAAAAAGAGGGAGAGAGAGAGAA 23 12354 BCL11A-10383 + AAAAAAAGAGGGAGAGAGAGAGAA 24 12355 BCL11A-10384 + AGGGCGAGCAGGAGAGAA 18 12356 BCL11A-10385 + CAGGGCGAGCAGGAGAGAA 19 12357 BCL11A-4422 + GCAGGGCGAGCAGGAGAGAA 20 12358 BCL11A-10386 + GGCAGGGCGAGCAGGAGAGAA 21 12359 BCL11A-10387 + GGGCAGGGCGAGCAGGAGAGAA 22 12360 BCL11A-10388 + UGGGCAGGGCGAGCAGGAGAGAA 23 12361 BCL11A-10389 + AUGGGCAGGGCGAGCAGGAGAGAA 24 12362 BCL11A-10390 + GAGAAGGGGAGGAGGGAA 18 12363 BCL11A-10391 + AGAGAAGGGGAGGAGGGAA 19 12364 BCL11A-4404 + GAGAGAAGGGGAGGAGGGAA 20 12365 BCL11A-10392 + GGAGAGAAGGGGAGGAGGGAA 21 12366 BCL11A-10393 + AGGAGAGAAGGGGAGGAGGGAA 22 12367 BCL11A-10394 + CAGGAGAGAAGGGGAGGAGGGAA 23 12368 BCL11A-10395 + GCAGGAGAGAAGGGGAGGAGGGAA 24 12369 BCL11A-10396 + ACGACGGCUCGGUUCACA 18 12370 BCL11A-10397 + GACGACGGCUCGGUUCACA 19 12371 BCL11A-10398 + GGACGACGGCUCGGUUCACA 20 12372 BCL11A-10399 + CGGACGACGGCUCGGUUCACA 21 12373 BCL11A-10400 + GCGGACGACGGCUCGGUUCACA 22 12374 BCL11A-10401 + GGCGGACGACGGCUCGGUUCACA 23 12375 BCL11A-10402 + GGGCGGACGACGGCUCGGUUCACA 24 12376 BCL11A-10403 + AAGGGGAAGCUCACACCA 18 12377 BCL11A-10404 + GAAGGGGAAGCUCACACCA 19 12378 BCL11A-10405 + GGAAGGGGAAGCUCACACCA 20 12379 BCL11A-10406 + GGGAAGGGGAAGCUCACACCA 21 12380 BCL11A-10407 + AGGGAAGGGGAAGCUCACACCA 22 12381 BCL11A-10408 + GAGGGAAGGGGAAGCUCACACCA 23 12382 BCL11A-10409 + GGAGGGAAGGGGAAGCUCACACCA 24 12383 BCL11A-10410 + AGAAAGAAGGAGACUCCA 18 12384 BCL11A-10411 + UAGAAAGAAGGAGACUCCA 19 12385 BCL11A-10412 + UUAGAAAGAAGGAGACUCCA 20 12386 BCL11A-10413 + GUUAGAAAGAAGGAGACUCCA 21 12387 BCL11A-10414 + GGUUAGAAAGAAGGAGACUCCA 22 12388 BCL11A-10415 + GGGUUAGAAAGAAGGAGACUCCA 23 12389 BCL11A-10416 + CGGGUUAGAAAGAAGGAGACUCCA 24 12390 BCL11A-10417 + GGCUCACCAGUGGCCGCA 18 12391 BCL11A-10418 + GGGCUCACCAGUGGCCGCA 19 12392 BCL11A-10419 + CGGGCUCACCAGUGGCCGCA 20 12393 BCL11A-10420 + GCGGGCUCACCAGUGGCCGCA 21 12394 BCL11A-10421 + CGCGGGCUCACCAGUGGCCGCA 22 12395 BCL11A-10422 + CCGCGGGCUCACCAGUGGCCGCA 23 12396 BCL11A-10423 + GCCGCGGGCUCACCAGUGGCCGCA 24 12397 BCL11A-10424 + UAAUACAAAGAUGGCGCA 18 12398 BCL11A-10425 + AUAAUACAAAGAUGGCGCA 19 12399 BCL11A-9702 + AAUAAUACAAAGAUGGCGCA 20 12400 BCL11A-10426 + AAAUAAUACAAAGAUGGCGCA 21 12401 BCL11A-10427 + GAAAUAAUACAAAGAUGGCGCA 22 12402 BCL11A-10428 + AGAAAUAAUACAAAGAUGGCGCA 23 12403 BCL11A-10429 + UAGAAAUAAUACAAAGAUGGCGCA 24 12404 BCL11A-10430 + AAAAAAAAAAAAAAAAGA 18 12405 BCL11A-10431 + AAAAAAAAAAAAAAAAAGA 19 12406 BCL11A-4527 + AAAAAAAAAAAAAAAAAAGA 20 12407 BCL11A-10432 + AAAAAAAAAAAAAAAAAAAGA 21 12408 BCL11A-10433 + AAAAAAAAAAAAAAAAAAAAGA 22 12409 BCL11A-10434 + AAAAAAAAAAAAAAAAAAAAAGA 23 12410 BCL11A-10435 + AAAAAAAAAAAAAAAAAAAAAAGA 24 12411 BCL11A-10436 + AGAGCCGGGUUAGAAAGA 18 12412 BCL11A-10437 + GAGAGCCGGGUUAGAAAGA 19 12413 BCL11A-9708 + GGAGAGCCGGGUUAGAAAGA 20 12414 BCL11A-10438 + GGGAGAGCCGGGUUAGAAAGA 21 12415 BCL11A-10439 + CGGGAGAGCCGGGUUAGAAAGA 22 12416 BCL11A-10440 + UCGGGAGAGCCGGGUUAGAAAGA 23 12417 BCL11A-10441 + AUCGGGAGAGCCGGGUUAGAAAGA 24 12418 BCL11A-10442 + CGUGGCCGGGAGAGAAGA 18 12419 BCL11A-10443 + GCGUGGCCGGGAGAGAAGA 19 12420 BCL11A-10444 + GGCGUGGCCGGGAGAGAAGA 20 12421 BCL11A-10445 + UGGCGUGGCCGGGAGAGAAGA 21 12422 BCL11A-10446 + GUGGCGUGGCCGGGAGAGAAGA 22 12423 BCL11A-10447 + GGUGGCGUGGCCGGGAGAGAAGA 23 12424 BCL11A-10448 + CGGUGGCGUGGCCGGGAGAGAAGA 24 12425 BCL11A-10449 + AGAGAGAGAGAAGAGAGA 18 12426 BCL11A-10450 + GAGAGAGAGAGAAGAGAGA 19 12427 BCL11A-4845 + GGAGAGAGAGAGAAGAGAGA 20 12428 BCL11A-10451 + GGGAGAGAGAGAGAAGAGAGA 21 12429 BCL11A-10452 + AGGGAGAGAGAGAGAAGAGAGA 22 12430 BCL11A-10453 + GAGGGAGAGAGAGAGAAGAGAGA 23 12431 BCL11A-10454 + AGAGGGAGAGAGAGAGAAGAGAGA 24 12432 BCL11A-10455 + UAGAGGGAGAGAGAGAGA 18 12433 BCL11A-10456 + AUAGAGGGAGAGAGAGAGA 19 12434 BCL11A-10457 + GAUAGAGGGAGAGAGAGAGA 20 12435 BCL11A-10458 + AGAUAGAGGGAGAGAGAGAGA 21 12436 BCL11A-10459 + GAGAUAGAGGGAGAGAGAGAGA 22 12437 BCL11A-10460 + AGAGAUAGAGGGAGAGAGAGAGA 23 12438 BCL11A-10461 + GAGAGAUAGAGGGAGAGAGAGAGA 24 12439 BCL11A-10462 + GAUAGAGGGAGAGAGAGA 18 12440 BCL11A-10463 + AGAUAGAGGGAGAGAGAGA 19 12441 BCL11A-10464 + GAGAUAGAGGGAGAGAGAGA 20 12442 BCL11A-10465 + AGAGAUAGAGGGAGAGAGAGA 21 12443 BCL11A-10466 + GAGAGAUAGAGGGAGAGAGAGA 22 12444 BCL11A-10467 + AGAGAGAUAGAGGGAGAGAGAGA 23 12445 BCL11A-10468 + AAGAGAGAUAGAGGGAGAGAGAGA 24 12446 BCL11A-10469 + AAAAAAGAGGGAGAGAGA 18 12447 BCL11A-10470 + AAAAAAAGAGGGAGAGAGA 19 12448 BCL11A-4911 + AAAAAAAAGAGGGAGAGAGA 20 12449 BCL11A-10471 + AAAAAAAAAGAGGGAGAGAGA 21 12450 BCL11A-10472 + AAAAAAAAAAGAGGGAGAGAGA 22 12451 BCL11A-10473 + AAAAAAAAAAAGAGGGAGAGAGA 23 12452 BCL11A-10474 + AAAAAAAAAAAAGAGGGAGAGAGA 24 12453 BCL11A-10475 + GAGAUAGAGGGAGAGAGA 18 12454 BCL11A-10476 + AGAGAUAGAGGGAGAGAGA 19 12455 BCL11A-10477 + GAGAGAUAGAGGGAGAGAGA 20 12456 BCL11A-10478 + AGAGAGAUAGAGGGAGAGAGA 21 12457 BCL11A-10479 + AAGAGAGAUAGAGGGAGAGAGA 22 12458 BCL11A-10480 + GAAGAGAGAUAGAGGGAGAGAGA 23 12459 BCL11A-10481 + AGAAGAGAGAUAGAGGGAGAGAGA 24 12460 BCL11A-10482 + CAGGGCGAGCAGGAGAGA 18 12461 BCL11A-10483 + GCAGGGCGAGCAGGAGAGA 19 12462 BCL11A-4464 + GGCAGGGCGAGCAGGAGAGA 20 12463 BCL11A-10484 + GGGCAGGGCGAGCAGGAGAGA 21 12464 BCL11A-10485 + UGGGCAGGGCGAGCAGGAGAGA 22 12465 BCL11A-10486 + AUGGGCAGGGCGAGCAGGAGAGA 23 12466 BCL11A-10487 + CAUGGGCAGGGCGAGCAGGAGAGA 24 12467 BCL11A-10488 + AAAAAAAAGAGGGAGAGA 18 12468 BCL11A-10489 + AAAAAAAAAGAGGGAGAGA 19 12469 BCL11A-4909 + AAAAAAAAAAGAGGGAGAGA 20 12470 BCL11A-10490 + AAAAAAAAAAAGAGGGAGAGA 21 12471 BCL11A-10491 + AAAAAAAAAAAAGAGGGAGAGA 22 12472 BCL11A-10492 + AAAAAAAAAAAAAGAGGGAGAGA 23 12473 BCL11A-10493 + AAAAAAAAAAAAAAGAGGGAGAGA 24 12474 BCL11A-10494 + GAGAGAUAGAGGGAGAGA 18 12475 BCL11A-10495 + AGAGAGAUAGAGGGAGAGA 19 12476 BCL11A-10496 + AAGAGAGAUAGAGGGAGAGA 20 12477 BCL11A-10497 + GAAGAGAGAUAGAGGGAGAGA 21 12478 BCL11A-10498 + AGAAGAGAGAUAGAGGGAGAGA 22 12479 BCL11A-10499 + GAGAAGAGAGAUAGAGGGAGAGA 23 12480 BCL11A-10500 + AGAGAAGAGAGAUAGAGGGAGAGA 24 12481 BCL11A-10501 + AAAAAAAAAAGAGGGAGA 18 12482 BCL11A-10502 + AAAAAAAAAAAGAGGGAGA 19 12483 BCL11A-4907 + AAAAAAAAAAAAGAGGGAGA 20 12484 BCL11A-10503 + AAAAAAAAAAAAAGAGGGAGA 21 12485 BCL11A-10504 + AAAAAAAAAAAAAAGAGGGAGA 22 12486 BCL11A-10505 + AAAAAAAAAAAAAAAGAGGGAGA 23 12487 BCL11A-10506 + AAAAAAAAAAAAAAAAGAGGGAGA 24 12488 BCL11A-10507 + AAGAGAGAUAGAGGGAGA 18 12489 BCL11A-10508 + GAAGAGAGAUAGAGGGAGA 19 12490 BCL11A-10509 + AGAAGAGAGAUAGAGGGAGA 20 12491 BCL11A-10510 + GAGAAGAGAGAUAGAGGGAGA 21 12492 BCL11A-10511 + AGAGAAGAGAGAUAGAGGGAGA 22 12493 BCL11A-10512 + GAGAGAAGAGAGAUAGAGGGAGA 23 12494 BCL11A-10513 + AGAGAGAAGAGAGAUAGAGGGAGA 24 12495 BCL11A-10514 + AGAGAGAAGAGAGAUAGA 18 12496 BCL11A-10515 + GAGAGAGAAGAGAGAUAGA 19 12497 BCL11A-9709 + AGAGAGAGAAGAGAGAUAGA 20 12498 BCL11A-10516 + GAGAGAGAGAAGAGAGAUAGA 21 12499 BCL11A-10517 + AGAGAGAGAGAAGAGAGAUAGA 22 12500 BCL11A-10518 + GAGAGAGAGAGAAGAGAGAUAGA 23 12501 BCL11A-10519 + GGAGAGAGAGAGAAGAGAGAUAGA 24 12502 BCL11A-10520 + CGGGAGAGCCGGGUUAGA 18 12503 BCL11A-10521 + UCGGGAGAGCCGGGUUAGA 19 12504 BCL11A-10522 + AUCGGGAGAGCCGGGUUAGA 20 12505 BCL11A-10523 + CAUCGGGAGAGCCGGGUUAGA 21 12506 BCL11A-10524 + ACAUCGGGAGAGCCGGGUUAGA 22 12507 BCL11A-10525 + CACAUCGGGAGAGCCGGGUUAGA 23 12508 BCL11A-10526 + UCACAUCGGGAGAGCCGGGUUAGA 24 12509 BCL11A-10527 + GGGGGAGGGGCGGGCCGA 18 12510 BCL11A-10528 + CGGGGGAGGGGCGGGCCGA 19 12511 BCL11A-4648 + CCGGGGGAGGGGCGGGCCGA 20 12512 BCL11A-10529 + CCCGGGGGAGGGGCGGGCCGA 21 12513 BCL11A-10530 + CCCCGGGGGAGGGGCGGGCCGA 22 12514 BCL11A-10531 + CCCCCGGGGGAGGGGCGGGCCGA 23 12515 BCL11A-10532 + GCCCCCGGGGGAGGGGCGGGCCGA 24 12516 BCL11A-10533 + UGGGCAGGGCGAGCAGGA 18 12517 BCL11A-10534 + AUGGGCAGGGCGAGCAGGA 19 12518 BCL11A-10535 + CAUGGGCAGGGCGAGCAGGA 20 12519 BCL11A-10536 + ACAUGGGCAGGGCGAGCAGGA 21 12520 BCL11A-10537 + AACAUGGGCAGGGCGAGCAGGA 22 12521 BCL11A-10538 + AAACAUGGGCAGGGCGAGCAGGA 23 12522 BCL11A-10539 + AAAACAUGGGCAGGGCGAGCAGGA 24 12523 BCL11A-10540 + CAGGAGAGAAGGGGAGGA 18 12524 BCL11A-10541 + GCAGGAGAGAAGGGGAGGA 19 12525 BCL11A-4584 + AGCAGGAGAGAAGGGGAGGA 20 12526 BCL11A-10542 + GAGCAGGAGAGAAGGGGAGGA 21 12527 BCL11A-10543 + CGAGCAGGAGAGAAGGGGAGGA 22 12528 BCL11A-10544 + GCGAGCAGGAGAGAAGGGGAGGA 23 12529 BCL11A-10545 + GGCGAGCAGGAGAGAAGGGGAGGA 24 12530 BCL11A-10546 + AAAAAAAAAAAAGAGGGA 18 12531 BCL11A-10547 + AAAAAAAAAAAAAGAGGGA 19 12532 BCL11A-4905 + AAAAAAAAAAAAAAGAGGGA 20 12533 BCL11A-10548 + AAAAAAAAAAAAAAAGAGGGA 21 12534 BCL11A-10549 + AAAAAAAAAAAAAAAAGAGGGA 22 12535 BCL11A-10550 + AAAAAAAAAAAAAAAAAGAGGGA 23 12536 BCL11A-10551 + AAAAAAAAAAAAAAAAAAGAGGGA 24 12537 BCL11A-10552 + AGAAGAGAGAUAGAGGGA 18 12538 BCL11A-10553 + GAGAAGAGAGAUAGAGGGA 19 12539 BCL11A-10554 + AGAGAAGAGAGAUAGAGGGA 20 12540 BCL11A-10555 + GAGAGAAGAGAGAUAGAGGGA 21 12541 BCL11A-10556 + AGAGAGAAGAGAGAUAGAGGGA 22 12542 BCL11A-10557 + GAGAGAGAAGAGAGAUAGAGGGA 23 12543 BCL11A-10558 + AGAGAGAGAAGAGAGAUAGAGGGA 24 12544 BCL11A-10559 + AGAGAAGGGGAGGAGGGA 18 12545 BCL11A-10560 + GAGAGAAGGGGAGGAGGGA 19 12546 BCL11A-4459 + GGAGAGAAGGGGAGGAGGGA 20 12547 BCL11A-10561 + AGGAGAGAAGGGGAGGAGGGA 21 12548 BCL11A-10562 + CAGGAGAGAAGGGGAGGAGGGA 22 12549 BCL11A-10563 + GCAGGAGAGAAGGGGAGGAGGGA 23 12550 BCL11A-10564 + AGCAGGAGAGAAGGGGAGGAGGGA 24 12551 BCL11A-10565 + GCGGUGGCGUGGCCGGGA 18 12552 BCL11A-10566 + GGCGGUGGCGUGGCCGGGA 19 12553 BCL11A-10567 + CGGCGGUGGCGUGGCCGGGA 20 12554 BCL11A-10568 + GCGGCGGUGGCGUGGCCGGGA 21 12555 BCL11A-10569 + CGCGGCGGUGGCGUGGCCGGGA 22 12556 BCL11A-10570 + CCGCGGCGGUGGCGUGGCCGGGA 23 12557 BCL11A-10571 + GCCGCGGCGGUGGCGUGGCCGGGA 24 12558 BCL11A-10572 + AGGGGCGGGCCGAGGGGA 18 12559 BCL11A-10573 + GAGGGGCGGGCCGAGGGGA 19 12560 BCL11A-4461 + GGAGGGGCGGGCCGAGGGGA 20 12561 BCL11A-10574 + GGGAGGGGCGGGCCGAGGGGA 21 12562 BCL11A-10575 + GGGGAGGGGCGGGCCGAGGGGA 22 12563 BCL11A-10576 + GGGGGAGGGGCGGGCCGAGGGGA 23 12564 BCL11A-10577 + CGGGGGAGGGGCGGGCCGAGGGGA 24 12565 BCL11A-10578 + CAAUGGCCAGUGCGGGGA 18 12566 BCL11A-10579 + CCAAUGGCCAGUGCGGGGA 19 12567 BCL11A-9558 + GCCAAUGGCCAGUGCGGGGA 20 12568 BCL11A-10580 + AGCCAAUGGCCAGUGCGGGGA 21 12569 BCL11A-10581 + AAGCCAAUGGCCAGUGCGGGGA 22 12570 BCL11A-10582 + CAAGCCAAUGGCCAGUGCGGGGA 23 12571 BCL11A-10583 + ACAAGCCAAUGGCCAGUGCGGGGA 24 12572 BCL11A-10584 + GUCAGGAGUCUGGAUGGA 18 12573 BCL11A-10585 + CGUCAGGAGUCUGGAUGGA 19 12574 BCL11A-10586 + ACGUCAGGAGUCUGGAUGGA 20 12575 BCL11A-10587 + AACGUCAGGAGUCUGGAUGGA 21 12576 BCL11A-10588 + GAACGUCAGGAGUCUGGAUGGA 22 12577 BCL11A-10589 + UGAACGUCAGGAGUCUGGAUGGA 23 12578 BCL11A-10590 + UUGAACGUCAGGAGUCUGGAUGGA 24 12579 BCL11A-10591 + AGAGAGAGAAGAGAGAUA 18 12580 BCL11A-10592 + GAGAGAGAGAAGAGAGAUA 19 12581 BCL11A-10593 + AGAGAGAGAGAAGAGAGAUA 20 12582 BCL11A-10594 + GAGAGAGAGAGAAGAGAGAUA 21 12583 BCL11A-10595 + GGAGAGAGAGAGAAGAGAGAUA 22 12584 BCL11A-10596 + GGGAGAGAGAGAGAAGAGAGAUA 23 12585 BCL11A-10597 + AGGGAGAGAGAGAGAAGAGAGAUA 24 12586 BCL11A-10598 + GACAGAGACACACAAAAC 18 12587 BCL11A-10599 + GGACAGAGACACACAAAAC 19 12588 BCL11A-10600 + UGGACAGAGACACACAAAAC 20 12589 BCL11A-10601 + AUGGACAGAGACACACAAAAC 21 12590 BCL11A-10602 + GAUGGACAGAGACACACAAAAC 22 12591 BCL11A-10603 + GGAUGGACAGAGACACACAAAAC 23 12592 BCL11A-10604 + UGGAUGGACAGAGACACACAAAAC 24 12593 BCL11A-10605 + CGUGACGUCCCUGCGAAC 18 12594 BCL11A-10606 + ACGUGACGUCCCUGCGAAC 19 12595 BCL11A-10607 + GACGUGACGUCCCUGCGAAC 20 12596 BCL11A-10608 + GGACGUGACGUCCCUGCGAAC 21 12597 BCL11A-10609 + CGGACGUGACGUCCCUGCGAAC 22 12598 BCL11A-10610 + GCGGACGUGACGUCCCUGCGAAC 23 12599 BCL11A-10611 + UGCGGACGUGACGUCCCUGCGAAC 24 12600 BCL11A-10612 + CUGCUCCCCCCCACACAC 18 12601 BCL11A-10613 + CCUGCUCCCCCCCACACAC 19 12602 BCL11A-10614 + CCCUGCUCCCCCCCACACAC 20 12603 BCL11A-10615 + GCCCUGCUCCCCCCCACACAC 21 12604 BCL11A-10616 + CGCCCUGCUCCCCCCCACACAC 22 12605 BCL11A-10617 + GCGCCCUGCUCCCCCCCACACAC 23 12606 BCL11A-10618 + UGCGCCCUGCUCCCCCCCACACAC 24 12607 BCL11A-10619 + UGGACAUGAAAAAGAGAC 18 12608 BCL11A-10620 + CUGGACAUGAAAAAGAGAC 19 12609 BCL11A-10621 + GCUGGACAUGAAAAAGAGAC 20 12610 BCL11A-10622 + GGCUGGACAUGAAAAAGAGAC 21 12611 BCL11A-10623 + GGGCUGGACAUGAAAAAGAGAC 22 12612 BCL11A-10624 + GGGGCUGGACAUGAAAAAGAGAC 23 12613 BCL11A-10625 + AGGGGCUGGACAUGAAAAAGAGAC 24 12614 BCL11A-10626 + ACACAUCAGGGGCUGGAC 18 12615 BCL11A-10627 + CACACAUCAGGGGCUGGAC 19 12616 BCL11A-10628 + ACACACAUCAGGGGCUGGAC 20 12617 BCL11A-10629 + GACACACAUCAGGGGCUGGAC 21 12618 BCL11A-10630 + GGACACACAUCAGGGGCUGGAC 22 12619 BCL11A-10631 + UGGACACACAUCAGGGGCUGGAC 23 12620 BCL11A-10632 + AUGGACACACAUCAGGGGCUGGAC 24 12621 BCL11A-6411 + UAUUAUUGGGUUACUUAC 18 12622 BCL11A-6412 + CUAUUAUUGGGUUACUUAC 19 12623 BCL11A-6413 + ACUAUUAUUGGGUUACUUAC 20 12624 BCL11A-6414 + UACUAUUAUUGGGUUACUUAC 21 12625 BCL11A-6415 + UUACUAUUAUUGGGUUACUUAC 22 12626 BCL11A-6416 + AUUACUAUUAUUGGGUUACUUAC 23 12627 BCL11A-6417 + UAUUACUAUUAUUGGGUUACUUAC 24 12628 BCL11A-10633 + AAAAUGGCAAAAGCCCCC 18 12629 BCL11A-10634 + AAAAAUGGCAAAAGCCCCC 19 12630 BCL11A-10635 + AAAAAAUGGCAAAAGCCCCC 20 12631 BCL11A-10636 + AAAAAAAUGGCAAAAGCCCCC 21 12632 BCL11A-10637 + GAAAAAAAUGGCAAAAGCCCCC 22 12633 BCL11A-10638 + UGAAAAAAAUGGCAAAAGCCCCC 23 12634 BCL11A-10639 + AUGAAAAAAAUGGCAAAAGCCCCC 24 12635 BCL11A-10640 + ACGCCAGACGCGGCCCCC 18 12636 BCL11A-10641 + GACGCCAGACGCGGCCCCC 19 12637 BCL11A-4456 + GGACGCCAGACGCGGCCCCC 20 12638 BCL11A-10642 + CGGACGCCAGACGCGGCCCCC 21 12639 BCL11A-10643 + GCGGACGCCAGACGCGGCCCCC 22 12640 BCL11A-10644 + CGCGGACGCCAGACGCGGCCCCC 23 12641 BCL11A-10645 + CCGCGGACGCCAGACGCGGCCCCC 24 12642 BCL11A-10646 + GACGCCAGACGCGGCCCC 18 12643 BCL11A-10647 + GGACGCCAGACGCGGCCCC 19 12644 BCL11A-4362 + CGGACGCCAGACGCGGCCCC 20 12645 BCL11A-10648 + GCGGACGCCAGACGCGGCCCC 21 12646 BCL11A-10649 + CGCGGACGCCAGACGCGGCCCC 22 12647 BCL11A-10650 + CCGCGGACGCCAGACGCGGCCCC 23 12648 BCL11A-10651 + UCCGCGGACGCCAGACGCGGCCCC 24 12649 BCL11A-10652 + GGACGCCAGACGCGGCCC 18 12650 BCL11A-10653 + CGGACGCCAGACGCGGCCC 19 12651 BCL11A-4825 + GCGGACGCCAGACGCGGCCC 20 12652 BCL11A-10654 + CGCGGACGCCAGACGCGGCCC 21 12653 BCL11A-10655 + CCGCGGACGCCAGACGCGGCCC 22 12654 BCL11A-10656 + UCCGCGGACGCCAGACGCGGCCC 23 12655 BCL11A-10657 + CUCCGCGGACGCCAGACGCGGCCC 24 12656 BCL11A-10658 + CCGGGGGAGGGGCGGGCC 18 12657 BCL11A-10659 + CCCGGGGGAGGGGCGGGCC 19 12658 BCL11A-5064 + CCCCGGGGGAGGGGCGGGCC 20 12659 BCL11A-10660 + CCCCCGGGGGAGGGGCGGGCC 21 12660 BCL11A-10661 + GCCCCCGGGGGAGGGGCGGGCC 22 12661 BCL11A-10662 + GGCCCCCGGGGGAGGGGCGGGCC 23 12662 BCL11A-10663 + CGGCCCCCGGGGGAGGGGCGGGCC 24 12663 BCL11A-10664 + GGAGGGGGCGCUGGGGCC 18 12664 BCL11A-10665 + GGGAGGGGGCGCUGGGGCC 19 12665 BCL11A-10666 + GGGGAGGGGGCGCUGGGGCC 20 12666 BCL11A-10667 + AGGGGAGGGGGCGCUGGGGCC 21 12667 BCL11A-10668 + GAGGGGAGGGGGCGCUGGGGCC 22 12668 BCL11A-10669 + CGAGGGGAGGGGGCGCUGGGGCC 23 12669 BCL11A-10670 + CCGAGGGGAGGGGGCGCUGGGGCC 24 12670 BCL11A-10671 + CGCGGCGGUGGCGUGGCC 18 12671 BCL11A-10672 + CCGCGGCGGUGGCGUGGCC 19 12672 BCL11A-9718 + GCCGCGGCGGUGGCGUGGCC 20 12673 BCL11A-10673 + CGCCGCGGCGGUGGCGUGGCC 21 12674 BCL11A-10674 + GCGCCGCGGCGGUGGCGUGGCC 22 12675 BCL11A-10675 + AGCGCCGCGGCGGUGGCGUGGCC 23 12676 BCL11A-10676 + GAGCGCCGCGGCGGUGGCGUGGCC 24 12677 BCL11A-10677 + UGCGGGGCGGGGGGCUCC 18 12678 BCL11A-10678 + GUGCGGGGCGGGGGGCUCC 19 12679 BCL11A-10679 + GGUGCGGGGCGGGGGGCUCC 20 12680 BCL11A-10680 + AGGUGCGGGGCGGGGGGCUCC 21 12681 BCL11A-10681 + GAGGUGCGGGGCGGGGGGCUCC 22 12682 BCL11A-10682 + GGAGGUGCGGGGCGGGGGGCUCC 23 12683 BCL11A-10683 + GGGAGGUGCGGGGCGGGGGGCUCC 24 12684 BCL11A-10684 + AACAUGGGCAGGGCGAGC 18 12685 BCL11A-10685 + AAACAUGGGCAGGGCGAGC 19 12686 BCL11A-9721 + AAAACAUGGGCAGGGCGAGC 20 12687 BCL11A-10686 + CAAAACAUGGGCAGGGCGAGC 21 12688 BCL11A-10687 + ACAAAACAUGGGCAGGGCGAGC 22 12689 BCL11A-10688 + CACAAAACAUGGGCAGGGCGAGC 23 12690 BCL11A-10689 + ACACAAAACAUGGGCAGGGCGAGC 24 12691 BCL11A-10690 + GCCGAGGGGAGGGGGCGC 18 12692 BCL11A-10691 + GGCCGAGGGGAGGGGGCGC 19 12693 BCL11A-4490 + GGGCCGAGGGGAGGGGGCGC 20 12694 BCL11A-10692 + CGGGCCGAGGGGAGGGGGCGC 21 12695 BCL11A-10693 + GCGGGCCGAGGGGAGGGGGCGC 22 12696 BCL11A-10694 + GGCGGGCCGAGGGGAGGGGGCGC 23 12697 BCL11A-10695 + GGGCGGGCCGAGGGGAGGGGGCGC 24 12698 BCL11A-10696 + AUAAUACAAAGAUGGCGC 18 12699 BCL11A-10697 + AAUAAUACAAAGAUGGCGC 19 12700 BCL11A-9565 + AAAUAAUACAAAGAUGGCGC 20 12701 BCL11A-10698 + GAAAUAAUACAAAGAUGGCGC 21 12702 BCL11A-10699 + AGAAAUAAUACAAAGAUGGCGC 22 12703 BCL11A-10700 + UAGAAAUAAUACAAAGAUGGCGC 23 12704 BCL11A-10701 + UUAGAAAUAAUACAAAGAUGGCGC 24 12705 BCL11A-10702 + GAGGGGGAGGUGCGGGGC 18 12706 BCL11A-10703 + GGAGGGGGAGGUGCGGGGC 19 12707 BCL11A-9724 + GGGAGGGGGAGGUGCGGGGC 20 12708 BCL11A-10704 + GGGGAGGGGGAGGUGCGGGGC 21 12709 BCL11A-10705 + CGGGGAGGGGGAGGUGCGGGGC 22 12710 BCL11A-10706 + GCGGGGAGGGGGAGGUGCGGGGC 23 12711 BCL11A-10707 + UGCGGGGAGGGGGAGGUGCGGGGC 24 12712 BCL11A-10708 + CCGCGGCGGUGGCGUGGC 18 12713 BCL11A-10709 + GCCGCGGCGGUGGCGUGGC 19 12714 BCL11A-9725 + CGCCGCGGCGGUGGCGUGGC 20 12715 BCL11A-10710 + GCGCCGCGGCGGUGGCGUGGC 21 12716 BCL11A-10711 + AGCGCCGCGGCGGUGGCGUGGC 22 12717 BCL11A-10712 + GAGCGCCGCGGCGGUGGCGUGGC 23 12718 BCL11A-10713 + CGAGCGCCGCGGCGGUGGCGUGGC 24 12719 BCL11A-10714 + CAAGCCAAUGGCCAGUGC 18 12720 BCL11A-10715 + ACAAGCCAAUGGCCAGUGC 19 12721 BCL11A-9727 + GACAAGCCAAUGGCCAGUGC 20 12722 BCL11A-10716 + GGACAAGCCAAUGGCCAGUGC 21 12723 BCL11A-10717 + AGGACAAGCCAAUGGCCAGUGC 22 12724 BCL11A-10718 + CAGGACAAGCCAAUGGCCAGUGC 23 12725 BCL11A-10719 + CCAGGACAAGCCAAUGGCCAGUGC 24 12726 BCL11A-10720 + CACCAAUGGACACACAUC 18 12727 BCL11A-10721 + ACACCAAUGGACACACAUC 19 12728 BCL11A-9729 + CACACCAAUGGACACACAUC 20 12729 BCL11A-10722 + UCACACCAAUGGACACACAUC 21 12730 BCL11A-10723 + CUCACACCAAUGGACACACAUC 22 12731 BCL11A-10724 + GCUCACACCAAUGGACACACAUC 23 12732 BCL11A-10725 + AGCUCACACCAAUGGACACACAUC 24 12733 BCL11A-10726 + GACGGCUCGGUUCACAUC 18 12734 BCL11A-10727 + CGACGGCUCGGUUCACAUC 19 12735 BCL11A-9568 + ACGACGGCUCGGUUCACAUC 20 12736 BCL11A-10728 + GACGACGGCUCGGUUCACAUC 21 12737 BCL11A-10729 + GGACGACGGCUCGGUUCACAUC 22 12738 BCL11A-10730 + CGGACGACGGCUCGGUUCACAUC 23 12739 BCL11A-10731 + GCGGACGACGGCUCGGUUCACAUC 24 12740 BCL11A-10732 + UUAGAAAGAAGGAGACUC 18 12741 BCL11A-10733 + GUUAGAAAGAAGGAGACUC 19 12742 BCL11A-10734 + GGUUAGAAAGAAGGAGACUC 20 12743 BCL11A-10735 + GGGUUAGAAAGAAGGAGACUC 21 12744 BCL11A-10736 + CGGGUUAGAAAGAAGGAGACUC 22 12745 BCL11A-10737 + CCGGGUUAGAAAGAAGGAGACUC 23 12746 BCL11A-10738 + GCCGGGUUAGAAAGAAGGAGACUC 24 12747 BCL11A-10739 + UCUCUUUUACCUCGACUC 18 12748 BCL11A-10740 + AUCUCUUUUACCUCGACUC 19 12749 BCL11A-10741 + UAUCUCUUUUACCUCGACUC 20 12750 BCL11A-10742 + UUAUCUCUUUUACCUCGACUC 21 12751 BCL11A-10743 + UUUAUCUCUUUUACCUCGACUC 22 12752 BCL11A-10744 + CUUUAUCUCUUUUACCUCGACUC 23 12753 BCL11A-10745 + CCUUUAUCUCUUUUACCUCGACUC 24 12754 BCL11A-10746 + CUCUCGGAGGUUUUUCUC 18 12755 BCL11A-10747 + ACUCUCGGAGGUUUUUCUC 19 12756 BCL11A-10748 + GACUCUCGGAGGUUUUUCUC 20 12757 BCL11A-10749 + CGACUCUCGGAGGUUUUUCUC 21 12758 BCL11A-10750 + UCGACUCUCGGAGGUUUUUCUC 22 12759 BCL11A-10751 + CUCGACUCUCGGAGGUUUUUCUC 23 12760 BCL11A-10752 + CCUCGACUCUCGGAGGUUUUUCUC 24 12761 BCL11A-10753 + AAAAAAAAAAAAAAAAAG 18 12762 BCL11A-10754 + AAAAAAAAAAAAAAAAAAG 19 12763 BCL11A-4526 + AAAAAAAAAAAAAAAAAAAG 20 12764 BCL11A-10755 + AAAAAAAAAAAAAAAAAAAAG 21 12765 BCL11A-10756 + AAAAAAAAAAAAAAAAAAAAAG 22 12766 BCL11A-10757 + AAAAAAAAAAAAAAAAAAAAAAG 23 12767 BCL11A-10758 + AAAAAAAAAAAAAAAAAAAAAAAG 24 12768 BCL11A-10759 + GAGAGCCGGGUUAGAAAG 18 12769 BCL11A-10760 + GGAGAGCCGGGUUAGAAAG 19 12770 BCL11A-10761 + GGGAGAGCCGGGUUAGAAAG 20 12771 BCL11A-10762 + CGGGAGAGCCGGGUUAGAAAG 21 12772 BCL11A-10763 + UCGGGAGAGCCGGGUUAGAAAG 22 12773 BCL11A-10764 + AUCGGGAGAGCCGGGUUAGAAAG 23 12774 BCL11A-10765 + CAUCGGGAGAGCCGGGUUAGAAAG 24 12775 BCL11A-10766 + GGGCGAGCAGGAGAGAAG 18 12776 BCL11A-10767 + AGGGCGAGCAGGAGAGAAG 19 12777 BCL11A-4629 + CAGGGCGAGCAGGAGAGAAG 20 12778 BCL11A-10768 + GCAGGGCGAGCAGGAGAGAAG 21 12779 BCL11A-10769 + GGCAGGGCGAGCAGGAGAGAAG 22 12780 BCL11A-10770 + GGGCAGGGCGAGCAGGAGAGAAG 23 12781 BCL11A-10771 + UGGGCAGGGCGAGCAGGAGAGAAG 24 12782 BCL11A-10772 + AGAAGGGGAGGAGGGAAG 18 12783 BCL11A-10773 + GAGAAGGGGAGGAGGGAAG 19 12784 BCL11A-4577 + AGAGAAGGGGAGGAGGGAAG 20 12785 BCL11A-10774 + GAGAGAAGGGGAGGAGGGAAG 21 12786 BCL11A-10775 + GGAGAGAAGGGGAGGAGGGAAG 22 12787 BCL11A-10776 + AGGAGAGAAGGGGAGGAGGGAAG 23 12788 BCL11A-10777 + CAGGAGAGAAGGGGAGGAGGGAAG 24 12789 BCL11A-10778 + ACACGGCAAUGGUUCCAG 18 12790 BCL11A-10779 + UACACGGCAAUGGUUCCAG 19 12791 BCL11A-10780 + AUACACGGCAAUGGUUCCAG 20 12792 BCL11A-10781 + CAUACACGGCAAUGGUUCCAG 21 12793 BCL11A-10782 + GCAUACACGGCAAUGGUUCCAG 22 12794 BCL11A-10783 + UGCAUACACGGCAAUGGUUCCAG 23 12795 BCL11A-10784 + GUGCAUACACGGCAAUGGUUCCAG 24 12796 BCL11A-10785 + CAUGGGCAGGGCGAGCAG 18 12797 BCL11A-10786 + ACAUGGGCAGGGCGAGCAG 19 12798 BCL11A-10787 + AACAUGGGCAGGGCGAGCAG 20 12799 BCL11A-10788 + AAACAUGGGCAGGGCGAGCAG 21 12800 BCL11A-10789 + AAAACAUGGGCAGGGCGAGCAG 22 12801 BCL11A-10790 + CAAAACAUGGGCAGGGCGAGCAG 23 12802 BCL11A-10791 + ACAAAACAUGGGCAGGGCGAGCAG 24 12803 BCL11A-10792 + GGAGAGAGAGAGAGAGAG 18 12804 BCL11A-10793 + GGGAGAGAGAGAGAGAGAG 19 12805 BCL11A-4999 + AGGGAGAGAGAGAGAGAGAG 20 12806 BCL11A-10794 + GAGGGAGAGAGAGAGAGAGAG 21 12807 BCL11A-10795 + AGAGGGAGAGAGAGAGAGAGAG 22 12808 BCL11A-10796 + UAGAGGGAGAGAGAGAGAGAGAG 23 12809 BCL11A-10797 + AUAGAGGGAGAGAGAGAGAGAGAG 24 12810 BCL11A-10798 + AAAGAGGGAGAGAGAGAG 18 12811 BCL11A-10799 + AAAAGAGGGAGAGAGAGAG 19 12812 BCL11A-4916 + AAAAAGAGGGAGAGAGAGAG 20 12813 BCL11A-10800 + AAAAAAGAGGGAGAGAGAGAG 21 12814 BCL11A-10801 + AAAAAAAGAGGGAGAGAGAGAG 22 12815 BCL11A-10802 + AAAAAAAAGAGGGAGAGAGAGAG 23 12816 BCL11A-10803 + AAAAAAAAAGAGGGAGAGAGAGAG 24 12817 BCL11A-10804 + GCAGGGCGAGCAGGAGAG 18 12818 BCL11A-10805 + GGCAGGGCGAGCAGGAGAG 19 12819 BCL11A-4870 + GGGCAGGGCGAGCAGGAGAG 20 12820 BCL11A-10806 + UGGGCAGGGCGAGCAGGAGAG 21 12821 BCL11A-10807 + AUGGGCAGGGCGAGCAGGAGAG 22 12822 BCL11A-10808 + CAUGGGCAGGGCGAGCAGGAGAG 23 12823 BCL11A-10809 + ACAUGGGCAGGGCGAGCAGGAGAG 24 12824 BCL11A-10810 + GUGGCGUGGCCGGGAGAG 18 12825 BCL11A-10811 + GGUGGCGUGGCCGGGAGAG 19 12826 BCL11A-10812 + CGGUGGCGUGGCCGGGAGAG 20 12827 BCL11A-10813 + GCGGUGGCGUGGCCGGGAGAG 21 12828 BCL11A-10814 + GGCGGUGGCGUGGCCGGGAGAG 22 12829 BCL11A-10815 + CGGCGGUGGCGUGGCCGGGAGAG 23 12830 BCL11A-10816 + GCGGCGGUGGCGUGGCCGGGAGAG 24 12831 BCL11A-10817 + GGGGAGGGGCGGGCCGAG 18 12832 BCL11A-10818 + GGGGGAGGGGCGGGCCGAG 19 12833 BCL11A-4677 + CGGGGGAGGGGCGGGCCGAG 20 12834 BCL11A-10819 + CCGGGGGAGGGGCGGGCCGAG 21 12835 BCL11A-10820 + CCCGGGGGAGGGGCGGGCCGAG 22 12836 BCL11A-10821 + CCCCGGGGGAGGGGCGGGCCGAG 23 12837 BCL11A-10822 + CCCCCGGGGGAGGGGCGGGCCGAG 24 12838 BCL11A-10823 + AAACAUGGGCAGGGCGAG 18 12839 BCL11A-10824 + AAAACAUGGGCAGGGCGAG 19 12840 BCL11A-10825 + CAAAACAUGGGCAGGGCGAG 20 12841 BCL11A-10826 + ACAAAACAUGGGCAGGGCGAG 21 12842 BCL11A-10827 + CACAAAACAUGGGCAGGGCGAG 22 12843 BCL11A-10828 + ACACAAAACAUGGGCAGGGCGAG 23 12844 BCL11A-10829 + CACACAAAACAUGGGCAGGGCGAG 24 12845 BCL11A-10830 + AGCAGGAGAGAAGGGGAG 18 12846 BCL11A-10831 + GAGCAGGAGAGAAGGGGAG 19 12847 BCL11A-5082 + CGAGCAGGAGAGAAGGGGAG 20 12848 BCL11A-10832 + GCGAGCAGGAGAGAAGGGGAG 21 12849 BCL11A-10833 + GGCGAGCAGGAGAGAAGGGGAG 22 12850 BCL11A-10834 + GGGCGAGCAGGAGAGAAGGGGAG 23 12851 BCL11A-10835 + AGGGCGAGCAGGAGAGAAGGGGAG 24 12852 BCL11A-10836 + AAUGGCCAGUGCGGGGAG 18 12853 BCL11A-10837 + CAAUGGCCAGUGCGGGGAG 19 12854 BCL11A-9572 + CCAAUGGCCAGUGCGGGGAG 20 12855 BCL11A-10838 + GCCAAUGGCCAGUGCGGGGAG 21 12856 BCL11A-10839 + AGCCAAUGGCCAGUGCGGGGAG 22 12857 BCL11A-10840 + AAGCCAAUGGCCAGUGCGGGGAG 23 12858 BCL11A-10841 + CAAGCCAAUGGCCAGUGCGGGGAG 24 12859 BCL11A-10842 + GAGAGAGAAGAGAGAUAG 18 12860 BCL11A-10843 + AGAGAGAGAAGAGAGAUAG 19 12861 BCL11A-9740 + GAGAGAGAGAAGAGAGAUAG 20 12862 BCL11A-10844 + AGAGAGAGAGAAGAGAGAUAG 21 12863 BCL11A-10845 + GAGAGAGAGAGAAGAGAGAUAG 22 12864 BCL11A-10846 + GGAGAGAGAGAGAAGAGAGAUAG 23 12865 BCL11A-10847 + GGGAGAGAGAGAGAAGAGAGAUAG 24 12866 BCL11A-10848 + CGCCAGACGCGGCCCCCG 18 12867 BCL11A-10849 + ACGCCAGACGCGGCCCCCG 19 12868 BCL11A-4351 + GACGCCAGACGCGGCCCCCG 20 12869 BCL11A-10850 + GGACGCCAGACGCGGCCCCCG 21 12870 BCL11A-10851 + CGGACGCCAGACGCGGCCCCCG 22 12871 BCL11A-10852 + GCGGACGCCAGACGCGGCCCCCG 23 12872 BCL11A-10853 + CGCGGACGCCAGACGCGGCCCCCG 24 12873 BCL11A-10854 + CGGGGGAGGGGCGGGCCG 18 12874 BCL11A-10855 + CCGGGGGAGGGGCGGGCCG 19 12875 BCL11A-4642 + CCCGGGGGAGGGGCGGGCCG 20 12876 BCL11A-10856 + CCCCGGGGGAGGGGCGGGCCG 21 12877 BCL11A-10857 + CCCCCGGGGGAGGGGCGGGCCG 22 12878 BCL11A-10858 + GCCCCCGGGGGAGGGGCGGGCCG 23 12879 BCL11A-10859 + GGCCCCCGGGGGAGGGGCGGGCCG 24 12880 BCL11A-10860 + GCGGCGGCGGCGGCGGCG 18 12881 BCL11A-10861 + GGCGGCGGCGGCGGCGGCG 19 12882 BCL11A-5097 + CGGCGGCGGCGGCGGCGGCG 20 12883 BCL11A-10862 + GCGGCGGCGGCGGCGGCGGCG 21 12884 BCL11A-10863 + GGCGGCGGCGGCGGCGGCGGCG 22 12885 BCL11A-10864 + CGGCGGCGGCGGCGGCGGCGGCG 23 12886 BCL11A-10865 + GCGGCGGCGGCGGCGGCGGCGGCG 24 12887 BCL11A-10866 + AGGGGGAGGUGCGGGGCG 18 12888 BCL11A-10867 + GAGGGGGAGGUGCGGGGCG 19 12889 BCL11A-9749 + GGAGGGGGAGGUGCGGGGCG 20 12890 BCL11A-10868 + GGGAGGGGGAGGUGCGGGGCG 21 12891 BCL11A-10869 + GGGGAGGGGGAGGUGCGGGGCG 22 12892 BCL11A-10870 + CGGGGAGGGGGAGGUGCGGGGCG 23 12893 BCL11A-10871 + GCGGGGAGGGGGAGGUGCGGGGCG 24 12894 BCL11A-10872 + GGCCGAGGGGAGGGGGCG 18 12895 BCL11A-10873 + GGGCCGAGGGGAGGGGGCG 19 12896 BCL11A-5099 + CGGGCCGAGGGGAGGGGGCG 20 12897 BCL11A-10874 + GCGGGCCGAGGGGAGGGGGCG 21 12898 BCL11A-10875 + GGCGGGCCGAGGGGAGGGGGCG 22 12899 BCL11A-10876 + GGGCGGGCCGAGGGGAGGGGGCG 23 12900 BCL11A-10877 + GGGGCGGGCCGAGGGGAGGGGGCG 24 12901 BCL11A-10878 + AAUAAUACAAAGAUGGCG 18 12902 BCL11A-10879 + AAAUAAUACAAAGAUGGCG 19 12903 BCL11A-10880 + GAAAUAAUACAAAGAUGGCG 20 12904 BCL11A-10881 + AGAAAUAAUACAAAGAUGGCG 21 12905 BCL11A-10882 + UAGAAAUAAUACAAAGAUGGCG 22 12906 BCL11A-10883 + UUAGAAAUAAUACAAAGAUGGCG 23 12907 BCL11A-10884 + AUUAGAAAUAAUACAAAGAUGGCG 24 12908 BCL11A-10885 + AAGCCAAUGGCCAGUGCG 18 12909 BCL11A-10886 + CAAGCCAAUGGCCAGUGCG 19 12910 BCL11A-9751 + ACAAGCCAAUGGCCAGUGCG 20 12911 BCL11A-10887 + GACAAGCCAAUGGCCAGUGCG 21 12912 BCL11A-10888 + GGACAAGCCAAUGGCCAGUGCG 22 12913 BCL11A-10889 + AGGACAAGCCAAUGGCCAGUGCG 23 12914 BCL11A-10890 + CAGGACAAGCCAAUGGCCAGUGCG 24 12915 BCL11A-6490 + GGGUUUGCCUUGCUUGCG 18 12916 BCL11A-6491 + GGGGUUUGCCUUGCUUGCG 19 12917 BCL11A-6492 + UGGGGUUUGCCUUGCUUGCG 20 12918 BCL11A-6493 + CUGGGGUUUGCCUUGCUUGCG 21 12919 BCL11A-6494 + GCUGGGGUUUGCCUUGCUUGCG 22 12920 BCL11A-6495 + UGCUGGGGUUUGCCUUGCUUGCG 23 12921 BCL11A-6496 + GUGCUGGGGUUUGCCUUGCUUGCG 24 12922 BCL11A-10891 + CAGGGGUGGGAGGAAAGG 18 12923 BCL11A-10892 + GCAGGGGUGGGAGGAAAGG 19 12924 BCL11A-10893 + GGCAGGGGUGGGAGGAAAGG 20 12925 BCL11A-10894 + UGGCAGGGGUGGGAGGAAAGG 21 12926 BCL11A-10895 + GUGGCAGGGGUGGGAGGAAAGG 22 12927 BCL11A-10896 + GGUGGCAGGGGUGGGAGGAAAGG 23 12928 BCL11A-10897 + GGGUGGCAGGGGUGGGAGGAAAGG 24 12929 BCL11A-10898 + ACACAAAACAUGGGCAGG 18 12930 BCL11A-10899 + CACACAAAACAUGGGCAGG 19 12931 BCL11A-10900 + ACACACAAAACAUGGGCAGG 20 12932 BCL11A-10901 + GACACACAAAACAUGGGCAGG 21 12933 BCL11A-10902 + AGACACACAAAACAUGGGCAGG 22 12934 BCL11A-10903 + GAGACACACAAAACAUGGGCAGG 23 12935 BCL11A-10904 + AGAGACACACAAAACAUGGGCAGG 24 12936 BCL11A-10905 + AAAAAAAAAAAAAAGAGG 18 12937 BCL11A-10906 + AAAAAAAAAAAAAAAGAGG 19 12938 BCL11A-4903 + AAAAAAAAAAAAAAAAGAGG 20 12939 BCL11A-10907 + AAAAAAAAAAAAAAAAAGAGG 21 12940 BCL11A-10908 + AAAAAAAAAAAAAAAAAAGAGG 22 12941 BCL11A-10909 + AAAAAAAAAAAAAAAAAAAGAGG 23 12942 BCL11A-10910 + AAAAAAAAAAAAAAAAAAAAGAGG 24 12943 BCL11A-10911 + AGAGAAGAGAGAUAGAGG 18 12944 BCL11A-10912 + GAGAGAAGAGAGAUAGAGG 19 12945 BCL11A-10913 + AGAGAGAAGAGAGAUAGAGG 20 12946 BCL11A-10914 + GAGAGAGAAGAGAGAUAGAGG 21 12947 BCL11A-10915 + AGAGAGAGAAGAGAGAUAGAGG 22 12948 BCL11A-10916 + GAGAGAGAGAAGAGAGAUAGAGG 23 12949 BCL11A-10917 + AGAGAGAGAGAAGAGAGAUAGAGG 24 12950 BCL11A-10918 + GCAGGAGAGAAGGGGAGG 18 12951 BCL11A-10919 + AGCAGGAGAGAAGGGGAGG 19 12952 BCL11A-4408 + GAGCAGGAGAGAAGGGGAGG 20 12953 BCL11A-10920 + CGAGCAGGAGAGAAGGGGAGG 21 12954 BCL11A-10921 + GCGAGCAGGAGAGAAGGGGAGG 22 12955 BCL11A-10922 + GGCGAGCAGGAGAGAAGGGGAGG 23 12956 BCL11A-10923 + GGGCGAGCAGGAGAGAAGGGGAGG 24 12957 BCL11A-10924 + AUGGCCAGUGCGGGGAGG 18 12958 BCL11A-10925 + AAUGGCCAGUGCGGGGAGG 19 12959 BCL11A-9756 + CAAUGGCCAGUGCGGGGAGG 20 12960 BCL11A-10926 + CCAAUGGCCAGUGCGGGGAGG 21 12961 BCL11A-10927 + GCCAAUGGCCAGUGCGGGGAGG 22 12962 BCL11A-10928 + AGCCAAUGGCCAGUGCGGGGAGG 23 12963 BCL11A-10929 + AAGCCAAUGGCCAGUGCGGGGAGG 24 12964 BCL11A-10930 + GCCAGACGCGGCCCCCGG 18 12965 BCL11A-10931 + CGCCAGACGCGGCCCCCGG 19 12966 BCL11A-4561 + ACGCCAGACGCGGCCCCCGG 20 12967 BCL11A-10932 + GACGCCAGACGCGGCCCCCGG 21 12968 BCL11A-10933 + GGACGCCAGACGCGGCCCCCGG 22 12969 BCL11A-10934 + CGGACGCCAGACGCGGCCCCCGG 23 12970 BCL11A-10935 + GCGGACGCCAGACGCGGCCCCCGG 24 12971 BCL11A-10936 + CGGCGGUGGCGUGGCCGG 18 12972 BCL11A-10937 + GCGGCGGUGGCGUGGCCGG 19 12973 BCL11A-10938 + CGCGGCGGUGGCGUGGCCGG 20 12974 BCL11A-10939 + CCGCGGCGGUGGCGUGGCCGG 21 12975 BCL11A-10940 + GCCGCGGCGGUGGCGUGGCCGG 22 12976 BCL11A-10941 + CGCCGCGGCGGUGGCGUGGCCGG 23 12977 BCL11A-10942 + GCGCCGCGGCGGUGGCGUGGCCGG 24 12978 BCL11A-10943 + CGGCGGCGGCGGCGGCGG 18 12979 BCL11A-10944 + GCGGCGGCGGCGGCGGCGG 19 12980 BCL11A-4479 + GGCGGCGGCGGCGGCGGCGG 20 12981 BCL11A-10945 + CGGCGGCGGCGGCGGCGGCGG 21 12982 BCL11A-10946 + GCGGCGGCGGCGGCGGCGGCGG 22 12983 BCL11A-10947 + GGCGGCGGCGGCGGCGGCGGCGG 23 12984 BCL11A-10948 + CGGCGGCGGCGGCGGCGGCGGCGG 24 12985 BCL11A-10949 + CGGCUCGGUUCACAUCGG 18 12986 BCL11A-10950 + ACGGCUCGGUUCACAUCGG 19 12987 BCL11A-10951 + GACGGCUCGGUUCACAUCGG 20 12988 BCL11A-10952 + CGACGGCUCGGUUCACAUCGG 21 12989 BCL11A-10953 + ACGACGGCUCGGUUCACAUCGG 22 12990 BCL11A-10954 + GACGACGGCUCGGUUCACAUCGG 23 12991 BCL11A-10955 + GGACGACGGCUCGGUUCACAUCGG 24 12992 BCL11A-10956 + AGGGGUGGGAGGAAAGGG 18 12993 BCL11A-10957 + CAGGGGUGGGAGGAAAGGG 19 12994 BCL11A-9759 + GCAGGGGUGGGAGGAAAGGG 20 12995 BCL11A-10958 + GGCAGGGGUGGGAGGAAAGGG 21 12996 BCL11A-10959 + UGGCAGGGGUGGGAGGAAAGGG 22 12997 BCL11A-10960 + GUGGCAGGGGUGGGAGGAAAGGG 23 12998 BCL11A-10961 + GGUGGCAGGGGUGGGAGGAAAGGG 24 12999 BCL11A-10962 + GCGAGCAGGAGAGAAGGG 18 13000 BCL11A-10963 + GGCGAGCAGGAGAGAAGGG 19 13001 BCL11A-4873 + GGGCGAGCAGGAGAGAAGGG 20 13002 BCL11A-10964 + AGGGCGAGCAGGAGAGAAGGG 21 13003 BCL11A-10965 + CAGGGCGAGCAGGAGAGAAGGG 22 13004 BCL11A-10966 + GCAGGGCGAGCAGGAGAGAAGGG 23 13005 BCL11A-10967 + GGCAGGGCGAGCAGGAGAGAAGGG 24 13006 BCL11A-10968 + AAGAAAGGGGUGGCAGGG 18 13007 BCL11A-10969 + GAAGAAAGGGGUGGCAGGG 19 13008 BCL11A-10970 + AGAAGAAAGGGGUGGCAGGG 20 13009 BCL11A-10971 + GAGAAGAAAGGGGUGGCAGGG 21 13010 BCL11A-10972 + AGAGAAGAAAGGGGUGGCAGGG 22 13011 BCL11A-10973 + GAGAGAAGAAAGGGGUGGCAGGG 23 13012 BCL11A-10974 + GGAGAGAAGAAAGGGGUGGCAGGG 24 13013 BCL11A-10975 + GGAGGGGCGGGCCGAGGG 18 13014 BCL11A-10976 + GGGAGGGGCGGGCCGAGGG 19 13015 BCL11A-4875 + GGGGAGGGGCGGGCCGAGGG 20 13016 BCL11A-10977 + GGGGGAGGGGCGGGCCGAGGG 21 13017 BCL11A-10978 + CGGGGGAGGGGCGGGCCGAGGG 22 13018 BCL11A-10979 + CCGGGGGAGGGGCGGGCCGAGGG 23 13019 BCL11A-10980 + CCCGGGGGAGGGGCGGGCCGAGGG 24 13020 BCL11A-10981 + GAGAGAAGGGGAGGAGGG 18 13021 BCL11A-10982 + GGAGAGAAGGGGAGGAGGG 19 13022 BCL11A-4998 + AGGAGAGAAGGGGAGGAGGG 20 13023 BCL11A-10983 + CAGGAGAGAAGGGGAGGAGGG 21 13024 BCL11A-10984 + GCAGGAGAGAAGGGGAGGAGGG 22 13025 BCL11A-10985 + AGCAGGAGAGAAGGGGAGGAGGG 23 13026 BCL11A-10986 + GAGCAGGAGAGAAGGGGAGGAGGG 24 13027 BCL11A-10987 + GCGGCCCCCGGGGGAGGG 18 13028 BCL11A-10988 + CGCGGCCCCCGGGGGAGGG 19 13029 BCL11A-4959 + ACGCGGCCCCCGGGGGAGGG 20 13030 BCL11A-10989 + GACGCGGCCCCCGGGGGAGGG 21 13031 BCL11A-10990 + AGACGCGGCCCCCGGGGGAGGG 22 13032 BCL11A-10991 + CAGACGCGGCCCCCGGGGGAGGG 23 13033 BCL11A-10992 + CCAGACGCGGCCCCCGGGGGAGGG 24 13034 BCL11A-10993 + CCCCGGGGGAGGGGCGGG 18 13035 BCL11A-10994 + CCCCCGGGGGAGGGGCGGG 19 13036 BCL11A-4817 + GCCCCCGGGGGAGGGGCGGG 20 13037 BCL11A-10995 + GGCCCCCGGGGGAGGGGCGGG 21 13038 BCL11A-10996 + CGGCCCCCGGGGGAGGGGCGGG 22 13039 BCL11A-10997 + GCGGCCCCCGGGGGAGGGGCGGG 23 13040 BCL11A-10998 + CGCGGCCCCCGGGGGAGGGGCGGG 24 13041 BCL11A-6504 + GACAUGGUGGGCUGCGGG 18 13042 BCL11A-6505 + AGACAUGGUGGGCUGCGGG 19 13043 BCL11A-6506 + GAGACAUGGUGGGCUGCGGG 20 13044 BCL11A-6507 + CGAGACAUGGUGGGCUGCGGG 21 13045 BCL11A-6508 + GCGAGACAUGGUGGGCUGCGGG 22 13046 BCL11A-6509 + GGCGAGACAUGGUGGGCUGCGGG 23 13047 BCL11A-6510 + CGGCGAGACAUGGUGGGCUGCGGG 24 13048 BCL11A-10999 + GCCAAUGGCCAGUGCGGG 18 13049 BCL11A-11000 + AGCCAAUGGCCAGUGCGGG 19 13050 BCL11A-11001 + AAGCCAAUGGCCAGUGCGGG 20 13051 BCL11A-11002 + CAAGCCAAUGGCCAGUGCGGG 21 13052 BCL11A-11003 + ACAAGCCAAUGGCCAGUGCGGG 22 13053 BCL11A-11004 + GACAAGCCAAUGGCCAGUGCGGG 23 13054 BCL11A-11005 + GGACAAGCCAAUGGCCAGUGCGGG 24 13055 BCL11A-11006 + GGGAGGGGGAGGUGCGGG 18 13056 BCL11A-11007 + GGGGAGGGGGAGGUGCGGG 19 13057 BCL11A-11008 + CGGGGAGGGGGAGGUGCGGG 20 13058 BCL11A-11009 + GCGGGGAGGGGGAGGUGCGGG 21 13059 BCL11A-11010 + UGCGGGGAGGGGGAGGUGCGGG 22 13060 BCL11A-11011 + GUGCGGGGAGGGGGAGGUGCGGG 23 13061 BCL11A-11012 + AGUGCGGGGAGGGGGAGGUGCGGG 24 13062 BCL11A-11013 + CGAGCAGGAGAGAAGGGG 18 13063 BCL11A-11014 + GCGAGCAGGAGAGAAGGGG 19 13064 BCL11A-4476 + GGCGAGCAGGAGAGAAGGGG 20 13065 BCL11A-11015 + GGGCGAGCAGGAGAGAAGGGG 21 13066 BCL11A-11016 + AGGGCGAGCAGGAGAGAAGGGG 22 13067 BCL11A-11017 + CAGGGCGAGCAGGAGAGAAGGGG 23 13068 BCL11A-11018 + GCAGGGCGAGCAGGAGAGAAGGGG 24 13069 BCL11A-11019 + AGAAAGGGGUGGCAGGGG 18 13070 BCL11A-11020 + AAGAAAGGGGUGGCAGGGG 19 13071 BCL11A-9762 + GAAGAAAGGGGUGGCAGGGG 20 13072 BCL11A-11021 + AGAAGAAAGGGGUGGCAGGGG 21 13073 BCL11A-11022 + GAGAAGAAAGGGGUGGCAGGGG 22 13074 BCL11A-11023 + AGAGAAGAAAGGGGUGGCAGGGG 23 13075 BCL11A-11024 + GAGAGAAGAAAGGGGUGGCAGGGG 24 13076 BCL11A-11025 + AUGGACACACAUCAGGGG 18 13077 BCL11A-11026 + AAUGGACACACAUCAGGGG 19 13078 BCL11A-11027 + CAAUGGACACACAUCAGGGG 20 13079 BCL11A-11028 + CCAAUGGACACACAUCAGGGG 21 13080 BCL11A-11029 + ACCAAUGGACACACAUCAGGGG 22 13081 BCL11A-11030 + CACCAAUGGACACACAUCAGGGG 23 13082 BCL11A-11031 + ACACCAAUGGACACACAUCAGGGG 24 13083 BCL11A-11032 + GAGGGGCGGGCCGAGGGG 18 13084 BCL11A-11033 + GGAGGGGCGGGCCGAGGGG 19 13085 BCL11A-4486 + GGGAGGGGCGGGCCGAGGGG 20 13086 BCL11A-11034 + GGGGAGGGGCGGGCCGAGGGG 21 13087 BCL11A-11035 + GGGGGAGGGGCGGGCCGAGGGG 22 13088 BCL11A-11036 + CGGGGGAGGGGCGGGCCGAGGGG 23 13089 BCL11A-11037 + CCGGGGGAGGGGCGGGCCGAGGGG 24 13090 BCL11A-11038 + CAGACGCGGCCCCCGGGG 18 13091 BCL11A-11039 + CCAGACGCGGCCCCCGGGG 19 13092 BCL11A-4816 + GCCAGACGCGGCCCCCGGGG 20 13093 BCL11A-11040 + CGCCAGACGCGGCCCCCGGGG 21 13094 BCL11A-11041 + ACGCCAGACGCGGCCCCCGGGG 22 13095 BCL11A-11042 + GACGCCAGACGCGGCCCCCGGGG 23 13096 BCL11A-11043 + GGACGCCAGACGCGGCCCCCGGGG 24 13097 BCL11A-11044 + CCAAUGGCCAGUGCGGGG 18 13098 BCL11A-11045 + GCCAAUGGCCAGUGCGGGG 19 13099 BCL11A-9763 + AGCCAAUGGCCAGUGCGGGG 20 13100 BCL11A-11046 + AAGCCAAUGGCCAGUGCGGGG 21 13101 BCL11A-11047 + CAAGCCAAUGGCCAGUGCGGGG 22 13102 BCL11A-11048 + ACAAGCCAAUGGCCAGUGCGGGG 23 13103 BCL11A-11049 + GACAAGCCAAUGGCCAGUGCGGGG 24 13104 BCL11A-11050 + GGAGGGGGAGGUGCGGGG 18 13105 BCL11A-11051 + GGGAGGGGGAGGUGCGGGG 19 13106 BCL11A-9764 + GGGGAGGGGGAGGUGCGGGG 20 13107 BCL11A-11052 + CGGGGAGGGGGAGGUGCGGGG 21 13108 BCL11A-11053 + GCGGGGAGGGGGAGGUGCGGGG 22 13109 BCL11A-11054 + UGCGGGGAGGGGGAGGUGCGGGG 23 13110 BCL11A-11055 + GUGCGGGGAGGGGGAGGUGCGGGG 24 13111 BCL11A-11056 + AGACGCGGCCCCCGGGGG 18 13112 BCL11A-11057 + CAGACGCGGCCCCCGGGGG 19 13113 BCL11A-4635 + CCAGACGCGGCCCCCGGGGG 20 13114 BCL11A-11058 + GCCAGACGCGGCCCCCGGGGG 21 13115 BCL11A-11059 + CGCCAGACGCGGCCCCCGGGGG 22 13116 BCL11A-11060 + ACGCCAGACGCGGCCCCCGGGGG 23 13117 BCL11A-11061 + GACGCCAGACGCGGCCCCCGGGGG 24 13118 BCL11A-11062 + UGGGAGGAAAGGGUGGGG 18 13119 BCL11A-11063 + GUGGGAGGAAAGGGUGGGG 19 13120 BCL11A-9766 + GGUGGGAGGAAAGGGUGGGG 20 13121 BCL11A-11064 + GGGUGGGAGGAAAGGGUGGGG 21 13122 BCL11A-11065 + GGGGUGGGAGGAAAGGGUGGGG 22 13123 BCL11A-11066 + AGGGGUGGGAGGAAAGGGUGGGG 23 13124 BCL11A-11067 + CAGGGGUGGGAGGAAAGGGUGGGG 24 13125 BCL11A-11068 + AGACACACAAAACAUGGG 18 13126 BCL11A-11069 + GAGACACACAAAACAUGGG 19 13127 BCL11A-11070 + AGAGACACACAAAACAUGGG 20 13128 BCL11A-11071 + CAGAGACACACAAAACAUGGG 21 13129 BCL11A-11072 + ACAGAGACACACAAAACAUGGG 22 13130 BCL11A-11073 + GACAGAGACACACAAAACAUGGG 23 13131 BCL11A-11074 + GGACAGAGACACACAAAACAUGGG 24 13132 BCL11A-11075 + GCAAUGGUUCCAGAUGGG 18 13133 BCL11A-11076 + GGCAAUGGUUCCAGAUGGG 19 13134 BCL11A-11077 + CGGCAAUGGUUCCAGAUGGG 20 13135 BCL11A-11078 + ACGGCAAUGGUUCCAGAUGGG 21 13136 BCL11A-11079 + CACGGCAAUGGUUCCAGAUGGG 22 13137 BCL11A-11080 + ACACGGCAAUGGUUCCAGAUGGG 23 13138 BCL11A-11081 + UACACGGCAAUGGUUCCAGAUGGG 24 13139 BCL11A-11082 + GUGGGAGGAAAGGGUGGG 18 13140 BCL11A-11083 + GGUGGGAGGAAAGGGUGGG 19 13141 BCL11A-9767 + GGGUGGGAGGAAAGGGUGGG 20 13142 BCL11A-11084 + GGGGUGGGAGGAAAGGGUGGG 21 13143 BCL11A-11085 + AGGGGUGGGAGGAAAGGGUGGG 22 13144 BCL11A-11086 + CAGGGGUGGGAGGAAAGGGUGGG 23 13145 BCL11A-11087 + GCAGGGGUGGGAGGAAAGGGUGGG 24 13146 BCL11A-11088 + AGGGGUGGCAGGGGUGGG 18 13147 BCL11A-11089 + AAGGGGUGGCAGGGGUGGG 19 13148 BCL11A-9768 + AAAGGGGUGGCAGGGGUGGG 20 13149 BCL11A-11090 + GAAAGGGGUGGCAGGGGUGGG 21 13150 BCL11A-11091 + AGAAAGGGGUGGCAGGGGUGGG 22 13151 BCL11A-11092 + AAGAAAGGGGUGGCAGGGGUGGG 23 13152 BCL11A-11093 + GAAGAAAGGGGUGGCAGGGGUGGG 24 13153 BCL11A-11094 + UGAACGUCAGGAGUCUGG 18 13154 BCL11A-11095 + UUGAACGUCAGGAGUCUGG 19 13155 BCL11A-11096 + CUUGAACGUCAGGAGUCUGG 20 13156 BCL11A-11097 + ACUUGAACGUCAGGAGUCUGG 21 13157 BCL11A-11098 + AACUUGAACGUCAGGAGUCUGG 22 13158 BCL11A-11099 + GAACUUGAACGUCAGGAGUCUGG 23 13159 BCL11A-11100 + CGAACUUGAACGUCAGGAGUCUGG 24 13160 BCL11A-11101 + GCCGCGGCGGUGGCGUGG 18 13161 BCL11A-11102 + CGCCGCGGCGGUGGCGUGG 19 13162 BCL11A-11103 + GCGCCGCGGCGGUGGCGUGG 20 13163 BCL11A-11104 + AGCGCCGCGGCGGUGGCGUGG 21 13164 BCL11A-11105 + GAGCGCCGCGGCGGUGGCGUGG 22 13165 BCL11A-11106 + CGAGCGCCGCGGCGGUGGCGUGG 23 13166 BCL11A-11107 + GCGAGCGCCGCGGCGGUGGCGUGG 24 13167 BCL11A-11108 + GGUGGGAGGAAAGGGUGG 18 13168 BCL11A-11109 + GGGUGGGAGGAAAGGGUGG 19 13169 BCL11A-9770 + GGGGUGGGAGGAAAGGGUGG 20 13170 BCL11A-11110 + AGGGGUGGGAGGAAAGGGUGG 21 13171 BCL11A-11111 + CAGGGGUGGGAGGAAAGGGUGG 22 13172 BCL11A-11112 + GCAGGGGUGGGAGGAAAGGGUGG 23 13173 BCL11A-11113 + GGCAGGGGUGGGAGGAAAGGGUGG 24 13174 BCL11A-11114 + GAGAGAAGAAAGGGGUGG 18 13175 BCL11A-11115 + GGAGAGAAGAAAGGGGUGG 19 13176 BCL11A-11116 + GGGAGAGAAGAAAGGGGUGG 20 13177 BCL11A-11117 + CGGGAGAGAAGAAAGGGGUGG 21 13178 BCL11A-11118 + CCGGGAGAGAAGAAAGGGGUGG 22 13179 BCL11A-11119 + GCCGGGAGAGAAGAAAGGGGUGG 23 13180 BCL11A-11120 + GGCCGGGAGAGAAGAAAGGGGUGG 24 13181 BCL11A-11121 + AAGGGGUGGCAGGGGUGG 18 13182 BCL11A-11122 + AAAGGGGUGGCAGGGGUGG 19 13183 BCL11A-11123 + GAAAGGGGUGGCAGGGGUGG 20 13184 BCL11A-11124 + AGAAAGGGGUGGCAGGGGUGG 21 13185 BCL11A-11125 + AAGAAAGGGGUGGCAGGGGUGG 22 13186 BCL11A-11126 + GAAGAAAGGGGUGGCAGGGGUGG 23 13187 BCL11A-11127 + AGAAGAAAGGGGUGGCAGGGGUGG 24 13188 BCL11A-11128 + AGGGAAGAUGAAUUGUGG 18 13189 BCL11A-11129 + CAGGGAAGAUGAAUUGUGG 19 13190 BCL11A-11130 + GCAGGGAAGAUGAAUUGUGG 20 13191 BCL11A-11131 + CGCAGGGAAGAUGAAUUGUGG 21 13192 BCL11A-11132 + GCGCAGGGAAGAUGAAUUGUGG 22 13193 BCL11A-11133 + GGCGCAGGGAAGAUGAAUUGUGG 23 13194 BCL11A-11134 + UGGCGCAGGGAAGAUGAAUUGUGG 24 13195 BCL11A-6524 + UGCUUGCGGCGAGACAUG 18 13196 BCL11A-6525 + UUGCUUGCGGCGAGACAUG 19 13197 BCL11A-6526 + CUUGCUUGCGGCGAGACAUG 20 13198 BCL11A-6527 + CCUUGCUUGCGGCGAGACAUG 21 13199 BCL11A-6528 + GCCUUGCUUGCGGCGAGACAUG 22 13200 BCL11A-6529 + UGCCUUGCUUGCGGCGAGACAUG 23 13201 BCL11A-6530 + UUGCCUUGCUUGCGGCGAGACAUG 24 13202 BCL11A-6544 + GCGAGACAUGGUGGGCUG 18 13203 BCL11A-6545 + GGCGAGACAUGGUGGGCUG 19 13204 BCL11A-5361 + CGGCGAGACAUGGUGGGCUG 20 13205 BCL11A-6546 + GCGGCGAGACAUGGUGGGCUG 21 13206 BCL11A-6547 + UGCGGCGAGACAUGGUGGGCUG 22 13207 BCL11A-6548 + UUGCGGCGAGACAUGGUGGGCUG 23 13208 BCL11A-6549 + CUUGCGGCGAGACAUGGUGGGCUG 24 13209 BCL11A-6550 + UUCCCGUUUGCUUAAGUG 18 13210 BCL11A-6551 + AUUCCCGUUUGCUUAAGUG 19 13211 BCL11A-6552 + AAUUCCCGUUUGCUUAAGUG 20 13212 BCL11A-6553 + GAAUUCCCGUUUGCUUAAGUG 21 13213 BCL11A-6554 + AGAAUUCCCGUUUGCUUAAGUG 22 13214 BCL11A-6555 + GAGAAUUCCCGUUUGCUUAAGUG 23 13215 BCL11A-6556 + CGAGAAUUCCCGUUUGCUUAAGUG 24 13216 BCL11A-11135 + ACAAGCCAAUGGCCAGUG 18 13217 BCL11A-11136 + GACAAGCCAAUGGCCAGUG 19 13218 BCL11A-9773 + GGACAAGCCAAUGGCCAGUG 20 13219 BCL11A-11137 + AGGACAAGCCAAUGGCCAGUG 21 13220 BCL11A-11138 + CAGGACAAGCCAAUGGCCAGUG 22 13221 BCL11A-11139 + CCAGGACAAGCCAAUGGCCAGUG 23 13222 BCL11A-11140 + ACCAGGACAAGCCAAUGGCCAGUG 24 13223 BCL11A-11141 + UGCGGGGAGGGGGAGGUG 18 13224 BCL11A-11142 + GUGCGGGGAGGGGGAGGUG 19 13225 BCL11A-9774 + AGUGCGGGGAGGGGGAGGUG 20 13226 BCL11A-11143 + CAGUGCGGGGAGGGGGAGGUG 21 13227 BCL11A-11144 + CCAGUGCGGGGAGGGGGAGGUG 22 13228 BCL11A-11145 + GCCAGUGCGGGGAGGGGGAGGUG 23 13229 BCL11A-11146 + GGCCAGUGCGGGGAGGGGGAGGUG 24 13230 BCL11A-11147 + GGGUGGGAGGAAAGGGUG 18 13231 BCL11A-11148 + GGGGUGGGAGGAAAGGGUG 19 13232 BCL11A-9775 + AGGGGUGGGAGGAAAGGGUG 20 13233 BCL11A-11149 + CAGGGGUGGGAGGAAAGGGUG 21 13234 BCL11A-11150 + GCAGGGGUGGGAGGAAAGGGUG 22 13235 BCL11A-11151 + GGCAGGGGUGGGAGGAAAGGGUG 23 13236 BCL11A-11152 + UGGCAGGGGUGGGAGGAAAGGGUG 24 13237 BCL11A-11153 + CGCAGGGAAGAUGAAUUG 18 13238 BCL11A-11154 + GCGCAGGGAAGAUGAAUUG 19 13239 BCL11A-9777 + GGCGCAGGGAAGAUGAAUUG 20 13240 BCL11A-11155 + UGGCGCAGGGAAGAUGAAUUG 21 13241 BCL11A-11156 + AUGGCGCAGGGAAGAUGAAUUG 22 13242 BCL11A-11157 + GAUGGCGCAGGGAAGAUGAAUUG 23 13243 BCL11A-11158 + AGAUGGCGCAGGGAAGAUGAAUUG 24 13244 BCL11A-11159 + UUGACAUCCAAAAUAAAU 18 13245 BCL11A-11160 + UUUGACAUCCAAAAUAAAU 19 13246 BCL11A-11161 + UUUUGACAUCCAAAAUAAAU 20 13247 BCL11A-11162 + CUUUUGACAUCCAAAAUAAAU 21 13248 BCL11A-11163 + CCUUUUGACAUCCAAAAUAAAU 22 13249 BCL11A-11164 + GCCUUUUGACAUCCAAAAUAAAU 23 13250 BCL11A-11165 + UGCCUUUUGACAUCCAAAAUAAAU 24 13251 BCL11A-11166 + ACACCAAUGGACACACAU 18 13252 BCL11A-11167 + CACACCAAUGGACACACAU 19 13253 BCL11A-11168 + UCACACCAAUGGACACACAU 20 13254 BCL11A-11169 + CUCACACCAAUGGACACACAU 21 13255 BCL11A-11170 + GCUCACACCAAUGGACACACAU 22 13256 BCL11A-11171 + AGCUCACACCAAUGGACACACAU 23 13257 BCL11A-11172 + AAGCUCACACCAAUGGACACACAU 24 13258 BCL11A-11173 + CGACGGCUCGGUUCACAU 18 13259 BCL11A-11174 + ACGACGGCUCGGUUCACAU 19 13260 BCL11A-9582 + GACGACGGCUCGGUUCACAU 20 13261 BCL11A-11175 + GGACGACGGCUCGGUUCACAU 21 13262 BCL11A-11176 + CGGACGACGGCUCGGUUCACAU 22 13263 BCL11A-11177 + GCGGACGACGGCUCGGUUCACAU 23 13264 BCL11A-11178 + GGCGGACGACGGCUCGGUUCACAU 24 13265 BCL11A-11179 + UGCGGACGUGACGUCCCU 18 13266 BCL11A-11180 + GUGCGGACGUGACGUCCCU 19 13267 BCL11A-11181 + AGUGCGGACGUGACGUCCCU 20 13268 BCL11A-11182 + AAGUGCGGACGUGACGUCCCU 21 13269 BCL11A-11183 + CAAGUGCGGACGUGACGUCCCU 22 13270 BCL11A-11184 + UCAAGUGCGGACGUGACGUCCCU 23 13271 BCL11A-11185 + UUCAAGUGCGGACGUGACGUCCCU 24 13272 BCL11A-6618 + GGCGAGACAUGGUGGGCU 18 13273 BCL11A-6619 + CGGCGAGACAUGGUGGGCU 19 13274 BCL11A-6620 + GCGGCGAGACAUGGUGGGCU 20 13275 BCL11A-6621 + UGCGGCGAGACAUGGUGGGCU 21 13276 BCL11A-6622 + UUGCGGCGAGACAUGGUGGGCU 22 13277 BCL11A-6623 + CUUGCGGCGAGACAUGGUGGGCU 23 13278 BCL11A-6624 + GCUUGCGGCGAGACAUGGUGGGCU 24 13279 BCL11A-11186 + CUCUUUUACCUCGACUCU 18 13280 BCL11A-11187 + UCUCUUUUACCUCGACUCU 19 13281 BCL11A-9585 + AUCUCUUUUACCUCGACUCU 20 13282 BCL11A-11188 + UAUCUCUUUUACCUCGACUCU 21 13283 BCL11A-11189 + UUAUCUCUUUUACCUCGACUCU 22 13284 BCL11A-11190 + UUUAUCUCUUUUACCUCGACUCU 23 13285 BCL11A-11191 + CUUUAUCUCUUUUACCUCGACUCU 24 13286 BCL11A-11192 + UGAGCUGCAAGUUCAAGU 18 13287 BCL11A-11193 + CUGAGCUGCAAGUUCAAGU 19 13288 BCL11A-11194 + CCUGAGCUGCAAGUUCAAGU 20 13289 BCL11A-11195 + CCCUGAGCUGCAAGUUCAAGU 21 13290 BCL11A-11196 + CCCCUGAGCUGCAAGUUCAAGU 22 13291 BCL11A-11197 + CCCCCUGAGCUGCAAGUUCAAGU 23 13292 BCL11A-11198 + CCCCCCUGAGCUGCAAGUUCAAGU 24 13293 BCL11A-11199 + GACAAGCCAAUGGCCAGU 18 13294 BCL11A-11200 + GGACAAGCCAAUGGCCAGU 19 13295 BCL11A-11201 + AGGACAAGCCAAUGGCCAGU 20 13296 BCL11A-11202 + CAGGACAAGCCAAUGGCCAGU 21 13297 BCL11A-11203 + CCAGGACAAGCCAAUGGCCAGU 22 13298 BCL11A-11204 + ACCAGGACAAGCCAAUGGCCAGU 23 13299 BCL11A-11205 + GACCAGGACAAGCCAAUGGCCAGU 24 13300 BCL11A-11206 + CCCUGCGAACUUGAACGU 18 13301 BCL11A-11207 + UCCCUGCGAACUUGAACGU 19 13302 BCL11A-11208 + GUCCCUGCGAACUUGAACGU 20 13303 BCL11A-11209 + CGUCCCUGCGAACUUGAACGU 21 13304 BCL11A-11210 + ACGUCCCUGCGAACUUGAACGU 22 13305 BCL11A-11211 + GACGUCCCUGCGAACUUGAACGU 23 13306 BCL11A-11212 + UGACGUCCCUGCGAACUUGAACGU 24 13307 BCL11A-11213 + GUGCGGGGAGGGGGAGGU 18 13308 BCL11A-11214 + AGUGCGGGGAGGGGGAGGU 19 13309 BCL11A-11215 + CAGUGCGGGGAGGGGGAGGU 20 13310 BCL11A-11216 + CCAGUGCGGGGAGGGGGAGGU 21 13311 BCL11A-11217 + GCCAGUGCGGGGAGGGGGAGGU 22 13312 BCL11A-11218 + GGCCAGUGCGGGGAGGGGGAGGU 23 13313 BCL11A-11219 + UGGCCAGUGCGGGGAGGGGGAGGU 24 13314 BCL11A-11220 + GGGGUGGGAGGAAAGGGU 18 13315 BCL11A-11221 + AGGGGUGGGAGGAAAGGGU 19 13316 BCL11A-9784 + CAGGGGUGGGAGGAAAGGGU 20 13317 BCL11A-11222 + GCAGGGGUGGGAGGAAAGGGU 21 13318 BCL11A-11223 + GGCAGGGGUGGGAGGAAAGGGU 22 13319 BCL11A-11224 + UGGCAGGGGUGGGAGGAAAGGGU 23 13320 BCL11A-11225 + GUGGCAGGGGUGGGAGGAAAGGGU 24 13321 BCL11A-11226 + ACAUCGGGAGAGCCGGGU 18 13322 BCL11A-11227 + CACAUCGGGAGAGCCGGGU 19 13323 BCL11A-11228 + UCACAUCGGGAGAGCCGGGU 20 13324 BCL11A-11229 + UUCACAUCGGGAGAGCCGGGU 21 13325 BCL11A-11230 + GUUCACAUCGGGAGAGCCGGGU 22 13326 BCL11A-11231 + GGUUCACAUCGGGAGAGCCGGGU 23 13327 BCL11A-11232 + CGGUUCACAUCGGGAGAGCCGGGU 24 13328 BCL11A-11233 + GAAAGGGGUGGCAGGGGU 18 13329 BCL11A-11234 + AGAAAGGGGUGGCAGGGGU 19 13330 BCL11A-9785 + AAGAAAGGGGUGGCAGGGGU 20 13331 BCL11A-11235 + GAAGAAAGGGGUGGCAGGGGU 21 13332 BCL11A-11236 + AGAAGAAAGGGGUGGCAGGGGU 22 13333 BCL11A-11237 + GAGAAGAAAGGGGUGGCAGGGGU 23 13334 BCL11A-11238 + AGAGAAGAAAGGGGUGGCAGGGGU 24 13335 BCL11A-11239 + GCAGGGAAGAUGAAUUGU 18 13336 BCL11A-11240 + CGCAGGGAAGAUGAAUUGU 19 13337 BCL11A-9786 + GCGCAGGGAAGAUGAAUUGU 20 13338 BCL11A-11241 + GGCGCAGGGAAGAUGAAUUGU 21 13339 BCL11A-11242 + UGGCGCAGGGAAGAUGAAUUGU 22 13340 BCL11A-11243 + AUGGCGCAGGGAAGAUGAAUUGU 23 13341 BCL11A-11244 + GAUGGCGCAGGGAAGAUGAAUUGU 24 13342 BCL11A-11245 + GCGCAGGGAAGAUGAAUU 18 13343 BCL11A-11246 + GGCGCAGGGAAGAUGAAUU 19 13344 BCL11A-11247 + UGGCGCAGGGAAGAUGAAUU 20 13345 BCL11A-11248 + AUGGCGCAGGGAAGAUGAAUU 21 13346 BCL11A-11249 + GAUGGCGCAGGGAAGAUGAAUU 22 13347 BCL11A-11250 + AGAUGGCGCAGGGAAGAUGAAUU 23 13348 BCL11A-11251 + AAGAUGGCGCAGGGAAGAUGAAUU 24 13349 BCL11A-11252 - GCAGGACUAGAAGCAAAA 18 13350 BCL11A-11253 - CGCAGGACUAGAAGCAAAA 19 13351 BCL11A-11254 - GCGCAGGACUAGAAGCAAAA 20 13352 BCL11A-11255 - CGCGCAGGACUAGAAGCAAAA 21 13353 BCL11A-11256 - GCGCGCAGGACUAGAAGCAAAA 22 13354 BCL11A-11257 - AGCGCGCAGGACUAGAAGCAAAA 23 13355 BCL11A-11258 - GAGCGCGCAGGACUAGAAGCAAAA 24 13356 BCL11A-6678 - CCCCAGCACUUAAGCAAA 18 13357 BCL11A-6679 - ACCCCAGCACUUAAGCAAA 19 13358 BCL11A-5443 - AACCCCAGCACUUAAGCAAA 20 13359 BCL11A-6680 - AAACCCCAGCACUUAAGCAAA 21 13360 BCL11A-6681 - CAAACCCCAGCACUUAAGCAAA 22 13361 BCL11A-6682 - GCAAACCCCAGCACUUAAGCAAA 23 13362 BCL11A-6683 - GGCAAACCCCAGCACUUAAGCAAA 24 13363 BCL11A-11259 - CGAGGUAAAAGAGAUAAA 18 13364 BCL11A-11260 - UCGAGGUAAAAGAGAUAAA 19 13365 BCL11A-9693 - GUCGAGGUAAAAGAGAUAAA 20 13366 BCL11A-11261 - AGUCGAGGUAAAAGAGAUAAA 21 13367 BCL11A-11262 - GAGUCGAGGUAAAAGAGAUAAA 22 13368 BCL11A-11263 - AGAGUCGAGGUAAAAGAGAUAAA 23 13369 BCL11A-11264 - GAGAGUCGAGGUAAAAGAGAUAAA 24 13370 BCL11A-6698 - ACCCCAGCACUUAAGCAA 18 13371 BCL11A-6699 - AACCCCAGCACUUAAGCAA 19 13372 BCL11A-6700 - AAACCCCAGCACUUAAGCAA 20 13373 BCL11A-6701 - CAAACCCCAGCACUUAAGCAA 21 13374 BCL11A-6702 - GCAAACCCCAGCACUUAAGCAA 22 13375 BCL11A-6703 - GGCAAACCCCAGCACUUAAGCAA 23 13376 BCL11A-6704 - AGGCAAACCCCAGCACUUAAGCAA 24 13377 BCL11A-11265 - CGGCUCUCCCGAUGUGAA 18 13378 BCL11A-11266 - CCGGCUCUCCCGAUGUGAA 19 13379 BCL11A-11267 - CCCGGCUCUCCCGAUGUGAA 20 13380 BCL11A-11268 - ACCCGGCUCUCCCGAUGUGAA 21 13381 BCL11A-11269 - AACCCGGCUCUCCCGAUGUGAA 22 13382 BCL11A-11270 - UAACCCGGCUCUCCCGAUGUGAA 23 13383 BCL11A-11271 - CUAACCCGGCUCUCCCGAUGUGAA 24 13384 BCL11A-11272 - UCGAGGUAAAAGAGAUAA 18 13385 BCL11A-11273 - GUCGAGGUAAAAGAGAUAA 19 13386 BCL11A-9699 - AGUCGAGGUAAAAGAGAUAA 20 13387 BCL11A-11274 - GAGUCGAGGUAAAAGAGAUAA 21 13388 BCL11A-11275 - AGAGUCGAGGUAAAAGAGAUAA 22 13389 BCL11A-11276 - GAGAGUCGAGGUAAAAGAGAUAA 23 13390 BCL11A-11277 - CGAGAGUCGAGGUAAAAGAGAUAA 24 13391 BCL11A-11278 - CUCCGAGAGUCGAGGUAA 18 13392 BCL11A-11279 - CCUCCGAGAGUCGAGGUAA 19 13393 BCL11A-11280 - ACCUCCGAGAGUCGAGGUAA 20 13394 BCL11A-11281 - AACCUCCGAGAGUCGAGGUAA 21 13395 BCL11A-11282 - AAACCUCCGAGAGUCGAGGUAA 22 13396 BCL11A-11283 - AAAACCUCCGAGAGUCGAGGUAA 23 13397 BCL11A-11284 - AAAAACCUCCGAGAGUCGAGGUAA 24 13398 BCL11A-11285 - ACUUGAACUUGCAGCUCA 18 13399 BCL11A-11286 - CACUUGAACUUGCAGCUCA 19 13400 BCL11A-9705 - GCACUUGAACUUGCAGCUCA 20 13401 BCL11A-11287 - CGCACUUGAACUUGCAGCUCA 21 13402 BCL11A-11288 - CCGCACUUGAACUUGCAGCUCA 22 13403 BCL11A-11289 - UCCGCACUUGAACUUGCAGCUCA 23 13404 BCL11A-11290 - GUCCGCACUUGAACUUGCAGCUCA 24 13405 BCL11A-11291 - GCAAAAGCGAGGGGGAGA 18 13406 BCL11A-11292 - AGCAAAAGCGAGGGGGAGA 19 13407 BCL11A-4934 - AAGCAAAAGCGAGGGGGAGA 20 13408 BCL11A-11293 - GAAGCAAAAGCGAGGGGGAGA 21 13409 BCL11A-11294 - AGAAGCAAAAGCGAGGGGGAGA 22 13410 BCL11A-11295 - UAGAAGCAAAAGCGAGGGGGAGA 23 13411 BCL11A-11296 - CUAGAAGCAAAAGCGAGGGGGAGA 24 13412 BCL11A-11297 - GACUAGAAGCAAAAGCGA 18 13413 BCL11A-11298 - GGACUAGAAGCAAAAGCGA 19 13414 BCL11A-9710 - AGGACUAGAAGCAAAAGCGA 20 13415 BCL11A-11299 - CAGGACUAGAAGCAAAAGCGA 21 13416 BCL11A-11300 - GCAGGACUAGAAGCAAAAGCGA 22 13417 BCL11A-11301 - CGCAGGACUAGAAGCAAAAGCGA 23 13418 BCL11A-11302 - GCGCAGGACUAGAAGCAAAAGCGA 24 13419 BCL11A-11303 - AAGCAAAAGCGAGGGGGA 18 13420 BCL11A-11304 - GAAGCAAAAGCGAGGGGGA 19 13421 BCL11A-4972 - AGAAGCAAAAGCGAGGGGGA 20 13422 BCL11A-11305 - UAGAAGCAAAAGCGAGGGGGA 21 13423 BCL11A-11306 - CUAGAAGCAAAAGCGAGGGGGA 22 13424 BCL11A-11307 - ACUAGAAGCAAAAGCGAGGGGGA 23 13425 BCL11A-11308 - GACUAGAAGCAAAAGCGAGGGGGA 24 13426 BCL11A-11309 - GUCGAGGUAAAAGAGAUA 18 13427 BCL11A-11310 - AGUCGAGGUAAAAGAGAUA 19 13428 BCL11A-11311 - GAGUCGAGGUAAAAGAGAUA 20 13429 BCL11A-11312 - AGAGUCGAGGUAAAAGAGAUA 21 13430 BCL11A-11313 - GAGAGUCGAGGUAAAAGAGAUA 22 13431 BCL11A-11314 - CGAGAGUCGAGGUAAAAGAGAUA 23 13432 BCL11A-11315 - CCGAGAGUCGAGGUAAAAGAGAUA 24 13433 BCL11A-11316 - GGGACGUCACGUCCGCAC 18 13434 BCL11A-11317 - AGGGACGUCACGUCCGCAC 19 13435 BCL11A-11318 - CAGGGACGUCACGUCCGCAC 20 13436 BCL11A-11319 - GCAGGGACGUCACGUCCGCAC 21 13437 BCL11A-11320 - CGCAGGGACGUCACGUCCGCAC 22 13438 BCL11A-11321 - UCGCAGGGACGUCACGUCCGCAC 23 13439 BCL11A-11322 - UUCGCAGGGACGUCACGUCCGCAC 24 13440 BCL11A-11323 - AUAAUUAUUAAUAAUCAC 18 13441 BCL11A-11324 - AAUAAUUAUUAAUAAUCAC 19 13442 BCL11A-11325 - UAAUAAUUAUUAAUAAUCAC 20 13443 BCL11A-11326 - AUAAUAAUUAUUAAUAAUCAC 21 13444 BCL11A-11327 - AAUAAUAAUUAUUAAUAAUCAC 22 13445 BCL11A-11328 - UAAUAAUAAUUAUUAAUAAUCAC 23 13446 BCL11A-11329 - GUAAUAAUAAUUAUUAAUAAUCAC 24 13447 BCL11A-11330 - CAUUUUUAAAUUUUUCAC 18 13448 BCL11A-11331 - GCAUUUUUAAAUUUUUCAC 19 13449 BCL11A-11332 - UGCAUUUUUAAAUUUUUCAC 20 13450 BCL11A-11333 - AUGCAUUUUUAAAUUUUUCAC 21 13451 BCL11A-11334 - CAUGCAUUUUUAAAUUUUUCAC 22 13452 BCL11A-11335 - GCAUGCAUUUUUAAAUUUUUCAC 23 13453 BCL11A-11336 - UGCAUGCAUUUUUAAAUUUUUCAC 24 13454 BCL11A-11337 - CACGAGAGCGCGCAGGAC 18 13455 BCL11A-11338 - UCACGAGAGCGCGCAGGAC 19 13456 BCL11A-11339 - AUCACGAGAGCGCGCAGGAC 20 13457 BCL11A-11340 - AAUCACGAGAGCGCGCAGGAC 21 13458 BCL11A-11341 - UAAUCACGAGAGCGCGCAGGAC 22 13459 BCL11A-11342 - AUAAUCACGAGAGCGCGCAGGAC 23 13460 BCL11A-11343 - AAUAAUCACGAGAGCGCGCAGGAC 24 13461 BCL11A-11344 - UCGGCCCGCCCCUCCCCC 18 13462 BCL11A-11345 - CUCGGCCCGCCCCUCCCCC 19 13463 BCL11A-9716 - CCUCGGCCCGCCCCUCCCCC 20 13464 BCL11A-11346 - CCCUCGGCCCGCCCCUCCCCC 21 13465 BCL11A-11347 - CCCCUCGGCCCGCCCCUCCCCC 22 13466 BCL11A-11348 - UCCCCUCGGCCCGCCCCUCCCCC 23 13467 BCL11A-11349 - CUCCCCUCGGCCCGCCCCUCCCCC 24 13468 BCL11A-11350 - CUCGGCCCGCCCCUCCCC 18 13469 BCL11A-11351 - CCUCGGCCCGCCCCUCCCC 19 13470 BCL11A-9717 - CCCUCGGCCCGCCCCUCCCC 20 13471 BCL11A-11352 - CCCCUCGGCCCGCCCCUCCCC 21 13472 BCL11A-11353 - UCCCCUCGGCCCGCCCCUCCCC 22 13473 BCL11A-11354 - CUCCCCUCGGCCCGCCCCUCCCC 23 13474 BCL11A-11355 - CCUCCCCUCGGCCCGCCCCUCCCC 24 13475 BCL11A-11356 - CCUCGGCCCGCCCCUCCC 18 13476 BCL11A-11357 - CCCUCGGCCCGCCCCUCCC 19 13477 BCL11A-11358 - CCCCUCGGCCCGCCCCUCCC 20 13478 BCL11A-11359 - UCCCCUCGGCCCGCCCCUCCC 21 13479 BCL11A-11360 - CUCCCCUCGGCCCGCCCCUCCC 22 13480 BCL11A-11361 - CCUCCCCUCGGCCCGCCCCUCCC 23 13481 BCL11A-11362 - CCCUCCCCUCGGCCCGCCCCUCCC 24 13482 BCL11A-11363 - GGGCCGCGUCUGGCGUCC 18 13483 BCL11A-11364 - GGGGCCGCGUCUGGCGUCC 19 13484 BCL11A-11365 - GGGGGCCGCGUCUGGCGUCC 20 13485 BCL11A-11366 - CGGGGGCCGCGUCUGGCGUCC 21 13486 BCL11A-11367 - CCGGGGGCCGCGUCUGGCGUCC 22 13487 BCL11A-11368 - CCCGGGGGCCGCGUCUGGCGUCC 23 13488 BCL11A-11369 - CCCCGGGGGCCGCGUCUGGCGUCC 24 13489 BCL11A-11370 - AGGACUAGAAGCAAAAGC 18 13490 BCL11A-11371 - CAGGACUAGAAGCAAAAGC 19 13491 BCL11A-11372 - GCAGGACUAGAAGCAAAAGC 20 13492 BCL11A-11373 - CGCAGGACUAGAAGCAAAAGC 21 13493 BCL11A-11374 - GCGCAGGACUAGAAGCAAAAGC 22 13494 BCL11A-11375 - CGCGCAGGACUAGAAGCAAAAGC 23 13495 BCL11A-11376 - GCGCGCAGGACUAGAAGCAAAAGC 24 13496 BCL11A-11377 - CCUGACGUUCAAGUUCGC 18 13497 BCL11A-11378 - UCCUGACGUUCAAGUUCGC 19 13498 BCL11A-9566 - CUCCUGACGUUCAAGUUCGC 20 13499 BCL11A-11379 - ACUCCUGACGUUCAAGUUCGC 21 13500 BCL11A-11380 - GACUCCUGACGUUCAAGUUCGC 22 13501 BCL11A-11381 - AGACUCCUGACGUUCAAGUUCGC 23 13502 BCL11A-11382 - CAGACUCCUGACGUUCAAGUUCGC 24 13503 BCL11A-11383 - UAAUAAUUAUUAAUAAUC 18 13504 BCL11A-11384 - AUAAUAAUUAUUAAUAAUC 19 13505 BCL11A-11385 - AAUAAUAAUUAUUAAUAAUC 20 13506 BCL11A-11386 - UAAUAAUAAUUAUUAAUAAUC 21 13507 BCL11A-11387 - GUAAUAAUAAUUAUUAAUAAUC 22 13508 BCL11A-11388 - AGUAAUAAUAAUUAUUAAUAAUC 23 13509 BCL11A-11389 - UAGUAAUAAUAAUUAUUAAUAAUC 24 13510 BCL11A-11390 - AAAAACCCUCAUCCCAUC 18 13511 BCL11A-11391 - AAAAAACCCUCAUCCCAUC 19 13512 BCL11A-9730 - GAAAAAACCCUCAUCCCAUC 20 13513 BCL11A-11392 - GGAAAAAACCCUCAUCCCAUC 21 13514 BCL11A-11393 - GGGAAAAAACCCUCAUCCCAUC 22 13515 BCL11A-11394 - GGGGAAAAAACCCUCAUCCCAUC 23 13516 BCL11A-11395 - GGGGGAAAAAACCCUCAUCCCAUC 24 13517 BCL11A-11396 - CACUUGAACUUGCAGCUC 18 13518 BCL11A-11397 - GCACUUGAACUUGCAGCUC 19 13519 BCL11A-9569 - CGCACUUGAACUUGCAGCUC 20 13520 BCL11A-11398 - CCGCACUUGAACUUGCAGCUC 21 13521 BCL11A-11399 - UCCGCACUUGAACUUGCAGCUC 22 13522 BCL11A-11400 - GUCCGCACUUGAACUUGCAGCUC 23 13523 BCL11A-11401 - CGUCCGCACUUGAACUUGCAGCUC 24 13524 BCL11A-11402 - UGCAUUUUUAAAUUUUUC 18 13525 BCL11A-11403 - AUGCAUUUUUAAAUUUUUC 19 13526 BCL11A-11404 - CAUGCAUUUUUAAAUUUUUC 20 13527 BCL11A-11405 - GCAUGCAUUUUUAAAUUUUUC 21 13528 BCL11A-11406 - UGCAUGCAUUUUUAAAUUUUUC 22 13529 BCL11A-11407 - GUGCAUGCAUUUUUAAAUUUUUC 23 13530 BCL11A-11408 - UGUGCAUGCAUUUUUAAAUUUUUC 24 13531 BCL11A-11409 - GAGGUAAAAGAGAUAAAG 18 13532 BCL11A-11410 - CGAGGUAAAAGAGAUAAAG 19 13533 BCL11A-9571 - UCGAGGUAAAAGAGAUAAAG 20 13534 BCL11A-11411 - GUCGAGGUAAAAGAGAUAAAG 21 13535 BCL11A-11412 - AGUCGAGGUAAAAGAGAUAAAG 22 13536 BCL11A-11413 - GAGUCGAGGUAAAAGAGAUAAAG 23 13537 BCL11A-11414 - AGAGUCGAGGUAAAAGAGAUAAAG 24 13538 BCL11A-11415 - CUUGAACUUGCAGCUCAG 18 13539 BCL11A-11416 - ACUUGAACUUGCAGCUCAG 19 13540 BCL11A-9738 - CACUUGAACUUGCAGCUCAG 20 13541 BCL11A-11417 - GCACUUGAACUUGCAGCUCAG 21 13542 BCL11A-11418 - CGCACUUGAACUUGCAGCUCAG 22 13543 BCL11A-11419 - CCGCACUUGAACUUGCAGCUCAG 23 13544 BCL11A-11420 - UCCGCACUUGAACUUGCAGCUCAG 24 13545 BCL11A-11421 - GAGAAAAACCUCCGAGAG 18 13546 BCL11A-11422 - CGAGAAAAACCUCCGAGAG 19 13547 BCL11A-11423 - ACGAGAAAAACCUCCGAGAG 20 13548 BCL11A-11424 - CACGAGAAAAACCUCCGAGAG 21 13549 BCL11A-11425 - UCACGAGAAAAACCUCCGAGAG 22 13550 BCL11A-11426 - UUCACGAGAAAAACCUCCGAGAG 23 13551 BCL11A-11427 - UUUCACGAGAAAAACCUCCGAGAG 24 13552 BCL11A-11428 - ACUAGAAGCAAAAGCGAG 18 13553 BCL11A-11429 - GACUAGAAGCAAAAGCGAG 19 13554 BCL11A-9739 - GGACUAGAAGCAAAAGCGAG 20 13555 BCL11A-11430 - AGGACUAGAAGCAAAAGCGAG 21 13556 BCL11A-11431 - CAGGACUAGAAGCAAAAGCGAG 22 13557 BCL11A-11432 - GCAGGACUAGAAGCAAAAGCGAG 23 13558 BCL11A-11433 - CGCAGGACUAGAAGCAAAAGCGAG 24 13559 BCL11A-11434 - CGCGUGUGUGGGGGGGAG 18 13560 BCL11A-11435 - CCGCGUGUGUGGGGGGGAG 19 13561 BCL11A-11436 - UCCGCGUGUGUGGGGGGGAG 20 13562 BCL11A-11437 - GUCCGCGUGUGUGGGGGGGAG 21 13563 BCL11A-11438 - AGUCCGCGUGUGUGGGGGGGAG 22 13564 BCL11A-11439 - GAGUCCGCGUGUGUGGGGGGGAG 23 13565 BCL11A-11440 - AGAGUCCGCGUGUGUGGGGGGGAG 24 13566 BCL11A-11441 - GGCCGCGUCUGGCGUCCG 18 13567 BCL11A-11442 - GGGCCGCGUCUGGCGUCCG 19 13568 BCL11A-9574 - GGGGCCGCGUCUGGCGUCCG 20 13569 BCL11A-11443 - GGGGGCCGCGUCUGGCGUCCG 21 13570 BCL11A-11444 - CGGGGGCCGCGUCUGGCGUCCG 22 13571 BCL11A-11445 - CCGGGGGCCGCGUCUGGCGUCCG 23 13572 BCL11A-11446 - CCCGGGGGCCGCGUCUGGCGUCCG 24 13573 BCL11A-11447 - GGACUAGAAGCAAAAGCG 18 13574 BCL11A-11448 - AGGACUAGAAGCAAAAGCG 19 13575 BCL11A-9748 - CAGGACUAGAAGCAAAAGCG 20 13576 BCL11A-11449 - GCAGGACUAGAAGCAAAAGCG 21 13577 BCL11A-11450 - CGCAGGACUAGAAGCAAAAGCG 22 13578 BCL11A-11451 - GCGCAGGACUAGAAGCAAAAGCG 23 13579 BCL11A-11452 - CGCGCAGGACUAGAAGCAAAAGCG 24 13580 BCL11A-11453 - AAUAAUCACGAGAGCGCG 18 13581 BCL11A-11454 - UAAUAAUCACGAGAGCGCG 19 13582 BCL11A-11455 - UUAAUAAUCACGAGAGCGCG 20 13583 BCL11A-11456 - AUUAAUAAUCACGAGAGCGCG 21 13584 BCL11A-11457 - UAUUAAUAAUCACGAGAGCGCG 22 13585 BCL11A-11458 - UUAUUAAUAAUCACGAGAGCGCG 23 13586 BCL11A-11459 - AUUAUUAAUAAUCACGAGAGCGCG 24 13587 BCL11A-11460 - UCCUGACGUUCAAGUUCG 18 13588 BCL11A-11461 - CUCCUGACGUUCAAGUUCG 19 13589 BCL11A-11462 - ACUCCUGACGUUCAAGUUCG 20 13590 BCL11A-11463 - GACUCCUGACGUUCAAGUUCG 21 13591 BCL11A-11464 - AGACUCCUGACGUUCAAGUUCG 22 13592 BCL11A-11465 - CAGACUCCUGACGUUCAAGUUCG 23 13593 BCL11A-11466 - CCAGACUCCUGACGUUCAAGUUCG 24 13594 BCL11A-11467 - AGGUAAAAGAGAUAAAGG 18 13595 BCL11A-11468 - GAGGUAAAAGAGAUAAAGG 19 13596 BCL11A-9753 - CGAGGUAAAAGAGAUAAAGG 20 13597 BCL11A-11469 - UCGAGGUAAAAGAGAUAAAGG 21 13598 BCL11A-11470 - GUCGAGGUAAAAGAGAUAAAGG 22 13599 BCL11A-11471 - AGUCGAGGUAAAAGAGAUAAAGG 23 13600 BCL11A-11472 - GAGUCGAGGUAAAAGAGAUAAAGG 24 13601 BCL11A-11473 - CUAGAAGCAAAAGCGAGG 18 13602 BCL11A-11474 - ACUAGAAGCAAAAGCGAGG 19 13603 BCL11A-9755 - GACUAGAAGCAAAAGCGAGG 20 13604 BCL11A-11475 - GGACUAGAAGCAAAAGCGAGG 21 13605 BCL11A-11476 - AGGACUAGAAGCAAAAGCGAGG 22 13606 BCL11A-11477 - CAGGACUAGAAGCAAAAGCGAGG 23 13607 BCL11A-11478 - GCAGGACUAGAAGCAAAAGCGAGG 24 13608 BCL11A-11479 - AGAAGCAAAAGCGAGGGG 18 13609 BCL11A-11480 - UAGAAGCAAAAGCGAGGGG 19 13610 BCL11A-11481 - CUAGAAGCAAAAGCGAGGGG 20 13611 BCL11A-11482 - ACUAGAAGCAAAAGCGAGGGG 21 13612 BCL11A-11483 - GACUAGAAGCAAAAGCGAGGGG 22 13613 BCL11A-11484 - GGACUAGAAGCAAAAGCGAGGGG 23 13614 BCL11A-11485 - AGGACUAGAAGCAAAAGCGAGGGG 24 13615 BCL11A-11486 - GAGUCCGCGUGUGUGGGG 18 13616 BCL11A-11487 - AGAGUCCGCGUGUGUGGGG 19 13617 BCL11A-9577 - UAGAGUCCGCGUGUGUGGGG 20 13618 BCL11A-11488 - UUAGAGUCCGCGUGUGUGGGG 21 13619 BCL11A-11489 - UUUAGAGUCCGCGUGUGUGGGG 22 13620 BCL11A-11490 - UUUUAGAGUCCGCGUGUGUGGGG 23 13621 BCL11A-11491 - AUUUUAGAGUCCGCGUGUGUGGGG 24 13622 BCL11A-11492 - AGAGUCCGCGUGUGUGGG 18 13623 BCL11A-11493 - UAGAGUCCGCGUGUGUGGG 19 13624 BCL11A-9769 - UUAGAGUCCGCGUGUGUGGG 20 13625 BCL11A-11494 - UUUAGAGUCCGCGUGUGUGGG 21 13626 BCL11A-11495 - UUUUAGAGUCCGCGUGUGUGGG 22 13627 BCL11A-11496 - AUUUUAGAGUCCGCGUGUGUGGG 23 13628 BCL11A-11497 - CAUUUUAGAGUCCGCGUGUGUGGG 24 13629 BCL11A-11498 - UAGAGUCCGCGUGUGUGG 18 13630 BCL11A-11499 - UUAGAGUCCGCGUGUGUGG 19 13631 BCL11A-9578 - UUUAGAGUCCGCGUGUGUGG 20 13632 BCL11A-11500 - UUUUAGAGUCCGCGUGUGUGG 21 13633 BCL11A-11501 - AUUUUAGAGUCCGCGUGUGUGG 22 13634 BCL11A-11502 - CAUUUUAGAGUCCGCGUGUGUGG 23 13635 BCL11A-11503 - UCAUUUUAGAGUCCGCGUGUGUGG 24 13636 BCL11A-11504 - CGCUCGCUGCGGCCACUG 18 13637 BCL11A-11505 - GCGCUCGCUGCGGCCACUG 19 13638 BCL11A-11506 - GGCGCUCGCUGCGGCCACUG 20 13639 BCL11A-11507 - CGGCGCUCGCUGCGGCCACUG 21 13640 BCL11A-11508 - GCGGCGCUCGCUGCGGCCACUG 22 13641 BCL11A-11509 - CGCGGCGCUCGCUGCGGCCACUG 23 13642 BCL11A-11510 - CCGCGGCGCUCGCUGCGGCCACUG 24 13643 BCL11A-11511 - GGAUGUCAAAAGGCACUG 18 13644 BCL11A-11512 - UGGAUGUCAAAAGGCACUG 19 13645 BCL11A-11513 - UUGGAUGUCAAAAGGCACUG 20 13646 BCL11A-11514 - UUUGGAUGUCAAAAGGCACUG 21 13647 BCL11A-11515 - UUUUGGAUGUCAAAAGGCACUG 22 13648 BCL11A-11516 - AUUUUGGAUGUCAAAAGGCACUG 23 13649 BCL11A-11517 - UAUUUUGGAUGUCAAAAGGCACUG 24 13650 BCL11A-11518 - UUUUAGAGUCCGCGUGUG 18 13651 BCL11A-11519 - AUUUUAGAGUCCGCGUGUG 19 13652 BCL11A-9581 - CAUUUUAGAGUCCGCGUGUG 20 13653 BCL11A-11520 - UCAUUUUAGAGUCCGCGUGUG 21 13654 BCL11A-11521 - UUCAUUUUAGAGUCCGCGUGUG 22 13655 BCL11A-11522 - UUUCAUUUUAGAGUCCGCGUGUG 23 13656 BCL11A-11523 - CUUUCAUUUUAGAGUCCGCGUGUG 24 13657 BCL11A-11524 - UUAGAGUCCGCGUGUGUG 18 13658 BCL11A-11525 - UUUAGAGUCCGCGUGUGUG 19 13659 BCL11A-9776 - UUUUAGAGUCCGCGUGUGUG 20 13660 BCL11A-11526 - AUUUUAGAGUCCGCGUGUGUG 21 13661 BCL11A-11527 - CAUUUUAGAGUCCGCGUGUGUG 22 13662 BCL11A-11528 - UCAUUUUAGAGUCCGCGUGUGUG 23 13663 BCL11A-11529 - UUCAUUUUAGAGUCCGCGUGUGUG 24 13664 BCL11A-11530 - AAAAAACCCUCAUCCCAU 18 13665 BCL11A-11531 - GAAAAAACCCUCAUCCCAU 19 13666 BCL11A-11532 - GGAAAAAACCCUCAUCCCAU 20 13667 BCL11A-11533 - GGGAAAAAACCCUCAUCCCAU 21 13668 BCL11A-11534 - GGGGAAAAAACCCUCAUCCCAU 22 13669 BCL11A-11535 - GGGGGAAAAAACCCUCAUCCCAU 23 13670 BCL11A-11536 - AGGGGGAAAAAACCCUCAUCCCAU 24 13671 BCL11A-11537 - UAACCCGGCUCUCCCGAU 18 13672 BCL11A-11538 - CUAACCCGGCUCUCCCGAU 19 13673 BCL11A-11539 - UCUAACCCGGCUCUCCCGAU 20 13674 BCL11A-11540 - UUCUAACCCGGCUCUCCCGAU 21 13675 BCL11A-11541 - UUUCUAACCCGGCUCUCCCGAU 22 13676 BCL11A-11542 - CUUUCUAACCCGGCUCUCCCGAU 23 13677 BCL11A-11543 - UCUUUCUAACCCGGCUCUCCCGAU 24 13678 BCL11A-11544 - UUUUCACGAGAAAAACCU 18 13679 BCL11A-11545 - UUUUUCACGAGAAAAACCU 19 13680 BCL11A-11546 - AUUUUUCACGAGAAAAACCU 20 13681 BCL11A-11547 - AAUUUUUCACGAGAAAAACCU 21 13682 BCL11A-11548 - AAAUUUUUCACGAGAAAAACCU 22 13683 BCL11A-11549 - UAAAUUUUUCACGAGAAAAACCU 23 13684 BCL11A-11550 - UUAAAUUUUUCACGAGAAAAACCU 24 13685 BCL11A-11551 - GCACUUGAACUUGCAGCU 18 13686 BCL11A-11552 - CGCACUUGAACUUGCAGCU 19 13687 BCL11A-11553 - CCGCACUUGAACUUGCAGCU 20 13688 BCL11A-11554 - UCCGCACUUGAACUUGCAGCU 21 13689 BCL11A-11555 - GUCCGCACUUGAACUUGCAGCU 22 13690 BCL11A-11556 - CGUCCGCACUUGAACUUGCAGCU 23 13691 BCL11A-11557 - ACGUCCGCACUUGAACUUGCAGCU 24 13692 BCL11A-11558 - CUGAUGAAGAUAUUUUCU 18 13693 BCL11A-11559 - ACUGAUGAAGAUAUUUUCU 19 13694 BCL11A-11560 - CACUGAUGAAGAUAUUUUCU 20 13695 BCL11A-11561 - GCACUGAUGAAGAUAUUUUCU 21 13696 BCL11A-11562 - GGCACUGAUGAAGAUAUUUUCU 22 13697 BCL11A-11563 - AGGCACUGAUGAAGAUAUUUUCU 23 13698 BCL11A-11564 - AAGGCACUGAUGAAGAUAUUUUCU 24 13699 BCL11A-11565 - UGAUGUGUGUCCAUUGGU 18 13700 BCL11A-11566 - CUGAUGUGUGUCCAUUGGU 19 13701 BCL11A-11567 - CCUGAUGUGUGUCCAUUGGU 20 13702 BCL11A-11568 - CCCUGAUGUGUGUCCAUUGGU 21 13703 BCL11A-11569 - CCCCUGAUGUGUGUCCAUUGGU 22 13704 BCL11A-11570 - GCCCCUGAUGUGUGUCCAUUGGU 23 13705 BCL11A-11571 - AGCCCCUGAUGUGUGUCCAUUGGU 24 13706 BCL11A-11572 - AUUUUAGAGUCCGCGUGU 18 13707 BCL11A-11573 - CAUUUUAGAGUCCGCGUGU 19 13708 BCL11A-11574 - UCAUUUUAGAGUCCGCGUGU 20 13709 BCL11A-11575 - UUCAUUUUAGAGUCCGCGUGU 21 13710 BCL11A-11576 - UUUCAUUUUAGAGUCCGCGUGU 22 13711 BCL11A-11577 - CUUUCAUUUUAGAGUCCGCGUGU 23 13712 BCL11A-11578 - UCUUUCAUUUUAGAGUCCGCGUGU 24 13713 BCL11A-11579 - UUUAGAGUCCGCGUGUGU 18 13714 BCL11A-11580 - UUUUAGAGUCCGCGUGUGU 19 13715 BCL11A-9586 - AUUUUAGAGUCCGCGUGUGU 20 13716 BCL11A-11581 - CAUUUUAGAGUCCGCGUGUGU 21 13717 BCL11A-11582 - UCAUUUUAGAGUCCGCGUGUGU 22 13718 BCL11A-11583 - UUCAUUUUAGAGUCCGCGUGUGU 23 13719 BCL11A-11584 - UUUCAUUUUAGAGUCCGCGUGUGU 24 13720 BCL11A-11585 - AUUGCCGUGUAUGCACUU 18 13721 BCL11A-11586 - CAUUGCCGUGUAUGCACUU 19 13722 BCL11A-11587 - CCAUUGCCGUGUAUGCACUU 20 13723 BCL11A-11588 - ACCAUUGCCGUGUAUGCACUU 21 13724 BCL11A-11589 - AACCAUUGCCGUGUAUGCACUU 22 13725 BCL11A-11590 - GAACCAUUGCCGUGUAUGCACUU 23 13726 BCL11A-11591 - GGAACCAUUGCCGUGUAUGCACUU 24 13727

Table 19D provides exemplary targeting domains for knocking down the BCL13A gene selected according to the fourth tier parameters. The targeting domains bind within the additional 500 bp (e.g., upstream or downstream) of a transcription start site (TSS), e.g., extending to 1 kb upstream and downstream of a TSS, and the PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL13A protein function, or the level of BCL11A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 19D 4th Tier DNA Target Site SEQ gRNA Name Strand Targeting Domain Length ID NO: BCL11A-11592 + CUCACCUCUUUUCUCCCC 18 13728 BCL11A-11593 + UCUCACCUCUUUUCUCCCC 19 13729 BCL11A-10076 + GUCUCACCUCUUUUCUCCCC 20 13730 BCL11A-11594 + AGUCUCACCUCUUUUCUCCCC 21 13731 BCL11A-11595 + CAGUCUCACCUCUUUUCUCCCC 22 13732 BCL11A-11596 + CCAGUCUCACCUCUUUUCUCCCC 23 13733 BCL11A-11597 + GCCAGUCUCACCUCUUUUCUCCCC 24 13734 BCL11A-11598 + AAAAGAAAAAAAUAGAGC 18 13735 BCL11A-11599 + AAAAAGAAAAAAAUAGAGC 19 13736 BCL11A-11600 + AAAAAAGAAAAAAAUAGAGC 20 13737 BCL11A-11601 + CAAAAAAGAAAAAAAUAGAGC 21 13738 BCL11A-11602 + UCAAAAAAGAAAAAAAUAGAGC 22 13739 BCL11A-11603 + UUCAAAAAAGAAAAAAAUAGAGC 23 13740 BCL11A-11604 + AUUCAAAAAAGAAAAAAAUAGAGC 24 13741 BCL11A-11605 + GGCGGGGCGGGGGGGGAG 18 13742 BCL11A-11606 + UGGCGGGGCGGGGGGGGAG 19 13743 BCL11A-10153 + CUGGCGGGGCGGGGGGGGAG 20 13744 BCL11A-11607 + ACUGGCGGGGCGGGGGGGGAG 21 13745 BCL11A-11608 + AACUGGCGGGGCGGGGGGGGAG 22 13746 BCL11A-11609 + AAACUGGCGGGGCGGGGGGGGAG 23 13747 BCL11A-11610 + AAAACUGGCGGGGCGGGGGGGGAG 24 13748 BCL11A-11611 + AGGGAGCGCACGGCAACG 18 13749 BCL11A-11612 + GAGGGAGCGCACGGCAACG 19 13750 BCL11A-10155 + GGAGGGAGCGCACGGCAACG 20 13751 BCL11A-11613 + GGGAGGGAGCGCACGGCAACG 21 13752 BCL11A-11614 + UGGGAGGGAGCGCACGGCAACG 22 13753 BCL11A-11615 + GUGGGAGGGAGCGCACGGCAACG 23 13754 BCL11A-11616 + GGUGGGAGGGAGCGCACGGCAACG 24 13755 BCL11A-11617 + CCCCCCCAUUUUCUUACG 18 13756 BCL11A-11618 + ACCCCCCCAUUUUCUUACG 19 13757 BCL11A-11619 + UACCCCCCCAUUUUCUUACG 20 13758 BCL11A-11620 + CUACCCCCCCAUUUUCUUACG 21 13759 BCL11A-11621 + CCUACCCCCCCAUUUUCUUACG 22 13760 BCL11A-11622 + CCCUACCCCCCCAUUUUCUUACG 23 13761 BCL11A-11623 + UCCCUACCCCCCCAUUUUCUUACG 24 13762 BCL11A-11624 + GGGCGGAGGGAAGCCAGG 18 13763 BCL11A-11625 + CGGGCGGAGGGAAGCCAGG 19 13764 BCL11A-11626 + GCGGGCGGAGGGAAGCCAGG 20 13765 BCL11A-11627 + CGCGGGCGGAGGGAAGCCAGG 21 13766 BCL11A-11628 + GCGCGGGCGGAGGGAAGCCAGG 22 13767 BCL11A-11629 + AGCGCGGGCGGAGGGAAGCCAGG 23 13768 BCL11A-11630 + AAGCGCGGGCGGAGGGAAGCCAGG 24 13769 BCL11A-11631 + CGGAAAGGAGGAAAGAGG 18 13770 BCL11A-11632 + GCGGAAAGGAGGAAAGAGG 19 13771 BCL11A-10187 + GGCGGAAAGGAGGAAAGAGG 20 13772 BCL11A-11633 + CGGCGGAAAGGAGGAAAGAGG 21 13773 BCL11A-11634 + GCGGCGGAAAGGAGGAAAGAGG 22 13774 BCL11A-11635 + AGCGGCGGAAAGGAGGAAAGAGG 23 13775 BCL11A-11636 + AAGCGGCGGAAAGGAGGAAAGAGG 24 13776 BCL11A-11637 + AAACUGGCGGGGCGGGGG 18 13777 BCL11A-11638 + AAAACUGGCGGGGCGGGGG 19 13778 BCL11A-10209 + CAAAACUGGCGGGGCGGGGG 20 13779 BCL11A-11639 + GCAAAACUGGCGGGGCGGGGG 21 13780 BCL11A-11640 + UGCAAAACUGGCGGGGCGGGGG 22 13781 BCL11A-11641 + UUGCAAAACUGGCGGGGCGGGGG 23 13782 BCL11A-11642 + UUUGCAAAACUGGCGGGGCGGGGG 24 13783 BCL11A-11643 + CCACCCCCAGGUUUGCAU 18 13784 BCL11A-11644 + CCCACCCCCAGGUUUGCAU 19 13785 BCL11A-11645 + UCCCACCCCCAGGUUUGCAU 20 13786 BCL11A-11646 + CUCCCACCCCCAGGUUUGCAU 21 13787 BCL11A-11647 + GCUCCCACCCCCAGGUUUGCAU 22 13788 BCL11A-11648 + AGCUCCCACCCCCAGGUUUGCAU 23 13789 BCL11A-11649 + CAGCUCCCACCCCCAGGUUUGCAU 24 13790 BCL11A-11650 + GCCUAAGUUUGGAGGGCU 18 13791 BCL11A-11651 + AGCCUAAGUUUGGAGGGCU 19 13792 BCL11A-11652 + CAGCCUAAGUUUGGAGGGCU 20 13793 BCL11A-11653 + CCAGCCUAAGUUUGGAGGGCU 21 13794 BCL11A-11654 + UCCAGCCUAAGUUUGGAGGGCU 22 13795 BCL11A-11655 + AUCCAGCCUAAGUUUGGAGGGCU 23 13796 BCL11A-11656 + AAUCCAGCCUAAGUUUGGAGGGCU 24 13797 BCL11A-11657 + CCACUUUCUCACUAUUGU 18 13798 BCL11A-11658 + GCCACUUUCUCACUAUUGU 19 13799 BCL11A-10251 + UGCCACUUUCUCACUAUUGU 20 13800 BCL11A-11659 + GUGCCACUUUCUCACUAUUGU 21 13801 BCL11A-11660 + AGUGCCACUUUCUCACUAUUGU 22 13802 BCL11A-11661 + CAGUGCCACUUUCUCACUAUUGU 23 13803 BCL11A-11662 + ACAGUGCCACUUUCUCACUAUUGU 24 13804 BCL11A-11663 - UUAUUUCUCUUUUCGAAA 18 13805 BCL11A-11664 - UUUAUUUCUCUUUUCGAAA 19 13806 BCL11A-10027 - CUUUAUUUCUCUUUUCGAAA 20 13807 BCL11A-11665 - GCUUUAUUUCUCUUUUCGAAA 21 13808 BCL11A-11666 - CGCUUUAUUUCUCUUUUCGAAA 22 13809 BCL11A-11667 - CCGCUUUAUUUCUCUUUUCGAAA 23 13810 BCL11A-11668 - GCCGCUUUAUUUCUCUUUUCGAAA 24 13811 BCL11A-11669 - CGGCGGCGGGGAGGGGAA 18 13812 BCL11A-11670 - GCGGCGGCGGGGAGGGGAA 19 13813 BCL11A-11671 - GGCGGCGGCGGGGAGGGGAA 20 13814 BCL11A-11672 - CGGCGGCGGCGGGGAGGGGAA 21 13815 BCL11A-11673 - GCGGCGGCGGCGGGGAGGGGAA 22 13816 BCL11A-11674 - CGCGGCGGCGGCGGGGAGGGGAA 23 13817 BCL11A-11675 - GCGCGGCGGCGGCGGGGAGGGGAA 24 13818 BCL11A-11676 - UGGGGGGGUAGGGAGGGA 18 13819 BCL11A-11677 - AUGGGGGGGUAGGGAGGGA 19 13820 BCL11A-11678 - AAUGGGGGGGUAGGGAGGGA 20 13821 BCL11A-11679 - AAAUGGGGGGGUAGGGAGGGA 21 13822 BCL11A-11680 - AAAAUGGGGGGGUAGGGAGGGA 22 13823 BCL11A-11681 - GAAAAUGGGGGGGUAGGGAGGGA 23 13824 BCL11A-11682 - AGAAAAUGGGGGGGUAGGGAGGGA 24 13825 BCL11A-11683 - AAAAUGGGGGGGUAGGGA 18 13826 BCL11A-11684 - GAAAAUGGGGGGGUAGGGA 19 13827 BCL11A-10049 - AGAAAAUGGGGGGGUAGGGA 20 13828 BCL11A-11685 - AAGAAAAUGGGGGGGUAGGGA 21 13829 BCL11A-11686 - UAAGAAAAUGGGGGGGUAGGGA 22 13830 BCL11A-11687 - GUAAGAAAAUGGGGGGGUAGGGA 23 13831 BCL11A-11688 - CGUAAGAAAAUGGGGGGGUAGGGA 24 13832 BCL11A-11689 - AAGGGGCCCCCGGCGCUC 18 13833 BCL11A-11690 - AAAGGGGCCCCCGGCGCUC 19 13834 BCL11A-11691 - GAAAGGGGCCCCCGGCGCUC 20 13835 BCL11A-11692 - GGAAAGGGGCCCCCGGCGCUC 21 13836 BCL11A-11693 - UGGAAAGGGGCCCCCGGCGCUC 22 13837 BCL11A-11694 - GUGGAAAGGGGCCCCCGGCGCUC 23 13838 BCL11A-11695 - UGUGGAAAGGGGCCCCCGGCGCUC 24 13839 BCL11A-11696 - CUUUUGUUCCGGCCAGAG 18 13840 BCL11A-11697 - CCUUUUGUUCCGGCCAGAG 19 13841 BCL11A-11698 - GCCUUUUGUUCCGGCCAGAG 20 13842 BCL11A-11699 - CGCCUUUUGUUCCGGCCAGAG 21 13843 BCL11A-11700 - CCGCCUUUUGUUCCGGCCAGAG 22 13844 BCL11A-11701 - GCCGCCUUUUGUUCCGGCCAGAG 23 13845 BCL11A-11702 - UGCCGCCUUUUGUUCCGGCCAGAG 24 13846 BCL11A-11703 - GUGGGUGUGCGUACGGAG 18 13847 BCL11A-11704 - AGUGGGUGUGCGUACGGAG 19 13848 BCL11A-11705 - AAGUGGGUGUGCGUACGGAG 20 13849 BCL11A-11706 - GAAGUGGGUGUGCGUACGGAG 21 13850 BCL11A-11707 - GGAAGUGGGUGUGCGUACGGAG 22 13851 BCL11A-11708 - GGGAAGUGGGUGUGCGUACGGAG 23 13852 BCL11A-11709 - GGGGAAGUGGGUGUGCGUACGGAG 24 13853 BCL11A-11710 - CCGGCGCUCCUGAGUCCG 18 13854 BCL11A-11711 - CCCGGCGCUCCUGAGUCCG 19 13855 BCL11A-10172 - CCCCGGCGCUCCUGAGUCCG 20 13856 BCL11A-11712 - CCCCCGGCGCUCCUGAGUCCG 21 13857 BCL11A-11713 - GCCCCCGGCGCUCCUGAGUCCG 22 13858 BCL11A-11714 - GGCCCCCGGCGCUCCUGAGUCCG 23 13859 BCL11A-11715 - GGGCCCCCGGCGCUCCUGAGUCCG 24 13860 BCL11A-11716 - CAGCCCUCCAAACUUAGG 18 13861 BCL11A-11717 - GCAGCCCUCCAAACUUAGG 19 13862 BCL11A-11718 - CGCAGCCCUCCAAACUUAGG 20 13863 BCL11A-11719 - CCGCAGCCCUCCAAACUUAGG 21 13864 BCL11A-11720 - CCCGCAGCCCUCCAAACUUAGG 22 13865 BCL11A-11721 - ACCCGCAGCCCUCCAAACUUAGG 23 13866 BCL11A-11722 - GACCCGCAGCCCUCCAAACUUAGG 24 13867 BCL11A-11723 - CUCACCGUAAGAAAAUGG 18 13868 BCL11A-11724 - ACUCACCGUAAGAAAAUGG 19 13869 BCL11A-10214 - CACUCACCGUAAGAAAAUGG 20 13870 BCL11A-11725 - CCACUCACCGUAAGAAAAUGG 21 13871 BCL11A-11726 - CCCACUCACCGUAAGAAAAUGG 22 13872 BCL11A-11727 - UCCCACUCACCGUAAGAAAAUGG 23 13873 BCL11A-11728 - UUCCCACUCACCGUAAGAAAAUGG 24 13874 BCL11A-11729 - GAGGCUCAGCUCUCAACU 18 13875 BCL11A-11730 - GGAGGCUCAGCUCUCAACU 19 13876 BCL11A-11731 - UGGAGGCUCAGCUCUCAACU 20 13877 BCL11A-11732 - UUGGAGGCUCAGCUCUCAACU 21 13878 BCL11A-11733 - CUUGGAGGCUCAGCUCUCAACU 22 13879 BCL11A-11734 - ACUUGGAGGCUCAGCUCUCAACU 23 13880 BCL11A-11735 - AACUUGGAGGCUCAGCUCUCAACU 24 13881 BCL11A-11736 - CAACUCACAUGCAAACCU 18 13882 BCL11A-11737 - ACAACUCACAUGCAAACCU 19 13883 BCL11A-10235 - AACAACUCACAUGCAAACCU 20 13884 BCL11A-11738 - GAACAACUCACAUGCAAACCU 21 13885 BCL11A-11739 - CGAACAACUCACAUGCAAACCU 22 13886 BCL11A-11740 - GCGAACAACUCACAUGCAAACCU 23 13887 BCL11A-11741 - UGCGAACAACUCACAUGCAAACCU 24 13888 BCL11A-10351 - UUGAAUAAUCUUUCAUUU 18 13889 BCL11A-10352 - UUUGAAUAAUCUUUCAUUU 19 13890 BCL11A-10353 - UUUUGAAUAAUCUUUCAUUU 20 13891 BCL11A-10354 - UUUUUGAAUAAUCUUUCAUUU 21 13892 BCL11A-10355 - UUUUUUGAAUAAUCUUUCAUUU 22 13893 BCL11A-10356 - CUUUUUUGAAUAAUCUUUCAUUU 23 13894 BCL11A-10357 - UCUUUUUUGAAUAAUCUUUCAUUU 24 13895 BCL11A-11742 - GCUCUAUUUUUUUCUUUU 18 13896 BCL11A-11743 - CGCUCUAUUUUUUUCUUUU 19 13897 BCL11A-11744 - UCGCUCUAUUUUUUUCUUUU 20 13898 BCL11A-11745 - CUCGCUCUAUUUUUUUCUUUU 21 13899 BCL11A-11746 - UCUCGCUCUAUUUUUUUCUUUU 22 13900 BCL11A-11747 - CUCUCGCUCUAUUUUUUUCUUUU 23 13901 BCL11A-11748 - ACUCUCGCUCUAUUUUUUUCUUUU 24 13902

Table 19E provides exemplary targeting domains for knocking down the BCL11A gene selected according to the fifth tier parameters. The targeting domains bind within the additional 500 bp (e.g., upstream or downstream) of a transcription start site (TSS), e.g., extending to 1 kb upstream and downstream of a TSS, and the PAM is NNGRRV. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL13A protein function, or the level of BCL11A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 19E 5th Tier Target DNA Site SEQ gRNA Name Strand Targeting Domain Length ID NO: BCL11A-11749 + AUUCAAAAAAGAAAAAAA 18 13903 BCL11A-11750 + UAUUCAAAAAAGAAAAAAA 19 13904 BCL11A-11751 + UUAUUCAAAAAAGAAAAAAA 20 13905 BCL11A-11752 + AUUAUUCAAAAAAGAAAAAAA 21 13906 BCL11A-11753 + GAUUAUUCAAAAAAGAAAAAAA 22 13907 BCL11A-11754 + AGAUUAUUCAAAAAAGAAAAAAA 23 13908 BCL11A-11755 + AAGAUUAUUCAAAAAAGAAAAAAA 24 13909 BCL11A-11756 + AUGAAAGAUUAUUCAAAA 18 13910 BCL11A-11757 + AAUGAAAGAUUAUUCAAAA 19 13911 BCL11A-11758 + AAAUGAAAGAUUAUUCAAAA 20 13912 BCL11A-11759 + AAAAUGAAAGAUUAUUCAAAA 21 13913 BCL11A-11760 + UAAAAUGAAAGAUUAUUCAAAA 22 13914 BCL11A-11761 + CUAAAAUGAAAGAUUAUUCAAAA 23 13915 BCL11A-11762 + UCUAAAAUGAAAGAUUAUUCAAAA 24 13916 BCL11A-11763 + UGCAUUCCUUUUCGAAAA 18 13917 BCL11A-11764 + UUGCAUUCCUUUUCGAAAA 19 13918 BCL11A-11765 + AUUGCAUUCCUUUUCGAAAA 20 13919 BCL11A-11766 + CAUUGCAUUCCUUUUCGAAAA 21 13920 BCL11A-11767 + UCAUUGCAUUCCUUUUCGAAAA 22 13921 BCL11A-11768 + AUCAUUGCAUUCCUUUUCGAAAA 23 13922 BCL11A-11769 + AAUCAUUGCAUUCCUUUUCGAAAA 24 13923 BCL11A-11770 + GCGGCGGAAAGGAGGAAA 18 13924 BCL11A-11771 + AGCGGCGGAAAGGAGGAAA 19 13925 BCL11A-11772 + AAGCGGCGGAAAGGAGGAAA 20 13926 BCL11A-11773 + AAAGCGGCGGAAAGGAGGAAA 21 13927 BCL11A-11774 + UAAAGCGGCGGAAAGGAGGAAA 22 13928 BCL11A-11775 + AUAAAGCGGCGGAAAGGAGGAAA 23 13929 BCL11A-11776 + AAUAAAGCGGCGGAAAGGAGGAAA 24 13930 BCL11A-11777 + GCCCGCGCGGCCUGGAAA 18 13931 BCL11A-11778 + AGCCCGCGCGGCCUGGAAA 19 13932 BCL11A-11779 + GAGCCCGCGCGGCCUGGAAA 20 13933 BCL11A-11780 + GGAGCCCGCGCGGCCUGGAAA 21 13934 BCL11A-11781 + AGGAGCCCGCGCGGCCUGGAAA 22 13935 BCL11A-11782 + CAGGAGCCCGCGCGGCCUGGAAA 23 13936 BCL11A-11783 + CCAGGAGCCCGCGCGGCCUGGAAA 24 13937 BCL11A-10371 + ACACACGCGGACUCUAAA 18 13938 BCL11A-10372 + CACACACGCGGACUCUAAA 19 13939 BCL11A-10373 + CCACACACGCGGACUCUAAA 20 13940 BCL11A-10374 + CCCACACACGCGGACUCUAAA 21 13941 BCL11A-10375 + CCCCACACACGCGGACUCUAAA 22 13942 BCL11A-10376 + CCCCCACACACGCGGACUCUAAA 23 13943 BCL11A-10377 + CCCCCCACACACGCGGACUCUAAA 24 13944 BCL11A-11784 + AUUGCAUUCCUUUUCGAA 18 13945 BCL11A-11785 + CAUUGCAUUCCUUUUCGAA 19 13946 BCL11A-11786 + UCAUUGCAUUCCUUUUCGAA 20 13947 BCL11A-11787 + AUCAUUGCAUUCCUUUUCGAA 21 13948 BCL11A-11788 + AAUCAUUGCAUUCCUUUUCGAA 22 13949 BCL11A-11789 + GAAUCAUUGCAUUCCUUUUCGAA 23 13950 BCL11A-11790 + GGAAUCAUUGCAUUCCUUUUCGAA 24 13951 BCL11A-11791 + AGAAAUAAAGCGGCGGAA 18 13952 BCL11A-11792 + GAGAAAUAAAGCGGCGGAA 19 13953 BCL11A-10031 + AGAGAAAUAAAGCGGCGGAA 20 13954 BCL11A-11793 + AAGAGAAAUAAAGCGGCGGAA 21 13955 BCL11A-11794 + AAAGAGAAAUAAAGCGGCGGAA 22 13956 BCL11A-11795 + AAAAGAGAAAUAAAGCGGCGGAA 23 13957 BCL11A-11796 + GAAAAGAGAAAUAAAGCGGCGGAA 24 13958 BCL11A-11797 + CCCGAGGAGAGGACAGCA 18 13959 BCL11A-11798 + GCCCGAGGAGAGGACAGCA 19 13960 BCL11A-11799 + UGCCCGAGGAGAGGACAGCA 20 13961 BCL11A-11800 + UUGCCCGAGGAGAGGACAGCA 21 13962 BCL11A-11801 + UUUGCCCGAGGAGAGGACAGCA 22 13963 BCL11A-11802 + CUUUGCCCGAGGAGAGGACAGCA 23 13964 BCL11A-11803 + ACUUUGCCCGAGGAGAGGACAGCA 24 13965 BCL11A-11804 + CCAAGUUACAGCUCCGCA 18 13966 BCL11A-11805 + UCCAAGUUACAGCUCCGCA 19 13967 BCL11A-11806 + CUCCAAGUUACAGCUCCGCA 20 13968 BCL11A-11807 + CCUCCAAGUUACAGCUCCGCA 21 13969 BCL11A-11808 + GCCUCCAAGUUACAGCUCCGCA 22 13970 BCL11A-11809 + AGCCUCCAAGUUACAGCUCCGCA 23 13971 BCL11A-11810 + GAGCCUCCAAGUUACAGCUCCGCA 24 13972 BCL11A-11811 + GAGCCGGCACAAAAGGCA 18 13973 BCL11A-11812 + GGAGCCGGCACAAAAGGCA 19 13974 BCL11A-11813 + AGGAGCCGGCACAAAAGGCA 20 13975 BCL11A-11814 + GAGGAGCCGGCACAAAAGGCA 21 13976 BCL11A-11815 + CGAGGAGCCGGCACAAAAGGCA 22 13977 BCL11A-11816 + GCGAGGAGCCGGCACAAAAGGCA 23 13978 BCL11A-11817 + CGCGAGGAGCCGGCACAAAAGGCA 24 13979 BCL11A-11818 + AAAUAGAGCGAGAGUGCA 18 13980 BCL11A-11819 + AAAAUAGAGCGAGAGUGCA 19 13981 BCL11A-11820 + AAAAAUAGAGCGAGAGUGCA 20 13982 BCL11A-11821 + AAAAAAUAGAGCGAGAGUGCA 21 13983 BCL11A-11822 + AAAAAAAUAGAGCGAGAGUGCA 22 13984 BCL11A-11823 + GAAAAAAAUAGAGCGAGAGUGCA 23 13985 BCL11A-11824 + AGAAAAAAAUAGAGCGAGAGUGCA 24 13986 BCL11A-11825 + CCGCGCGGCCUGGAAAGA 18 13987 BCL11A-11826 + CCCGCGCGGCCUGGAAAGA 19 13988 BCL11A-10040 + GCCCGCGCGGCCUGGAAAGA 20 13989 BCL11A-11827 + AGCCCGCGCGGCCUGGAAAGA 21 13990 BCL11A-11828 + GAGCCCGCGCGGCCUGGAAAGA 22 13991 BCL11A-11829 + GGAGCCCGCGCGGCCUGGAAAGA 23 13992 BCL11A-11830 + AGGAGCCCGCGCGGCCUGGAAAGA 24 13993 BCL11A-11831 + AAAAAAGAAAAAAAUAGA 18 13994 BCL11A-11832 + CAAAAAAGAAAAAAAUAGA 19 13995 BCL11A-11833 + UCAAAAAAGAAAAAAAUAGA 20 13996 BCL11A-11834 + UUCAAAAAAGAAAAAAAUAGA 21 13997 BCL11A-11835 + AUUCAAAAAAGAAAAAAAUAGA 22 13998 BCL11A-11836 + UAUUCAAAAAAGAAAAAAAUAGA 23 13999 BCL11A-11837 + UUAUUCAAAAAAGAAAAAAAUAGA 24 14000 BCL11A-11838 + CAGCUCCGCAGCGGGCGA 18 14001 BCL11A-11839 + ACAGCUCCGCAGCGGGCGA 19 14002 BCL11A-10044 + UACAGCUCCGCAGCGGGCGA 20 14003 BCL11A-11840 + UUACAGCUCCGCAGCGGGCGA 21 14004 BCL11A-11841 + GUUACAGCUCCGCAGCGGGCGA 22 14005 BCL11A-11842 + AGUUACAGCUCCGCAGCGGGCGA 23 14006 BCL11A-11843 + AAGUUACAGCUCCGCAGCGGGCGA 24 14007 BCL11A-11844 + GGAAACUUUGCCCGAGGA 18 14008 BCL11A-11845 + GGGAAACUUUGCCCGAGGA 19 14009 BCL11A-11846 + CGGGAAACUUUGCCCGAGGA 20 14010 BCL11A-11847 + UCGGGAAACUUUGCCCGAGGA 21 14011 BCL11A-11848 + CUCGGGAAACUUUGCCCGAGGA 22 14012 BCL11A-11849 + GCUCGGGAAACUUUGCCCGAGGA 23 14013 BCL11A-11850 + CGCUCGGGAAACUUUGCCCGAGGA 24 14014 BCL11A-11851 + AAGCGGCGGAAAGGAGGA 18 14015 BCL11A-11852 + AAAGCGGCGGAAAGGAGGA 19 14016 BCL11A-11853 + UAAAGCGGCGGAAAGGAGGA 20 14017 BCL11A-11854 + AUAAAGCGGCGGAAAGGAGGA 21 14018 BCL11A-11855 + AAUAAAGCGGCGGAAAGGAGGA 22 14019 BCL11A-11856 + AAAUAAAGCGGCGGAAAGGAGGA 23 14020 BCL11A-11857 + GAAAUAAAGCGGCGGAAAGGAGGA 24 14021 BCL11A-11858 + GAGAAAUAAAGCGGCGGA 18 14022 BCL11A-11859 + AGAGAAAUAAAGCGGCGGA 19 14023 BCL11A-11860 + AAGAGAAAUAAAGCGGCGGA 20 14024 BCL11A-11861 + AAAGAGAAAUAAAGCGGCGGA 21 14025 BCL11A-11862 + AAAAGAGAAAUAAAGCGGCGGA 22 14026 BCL11A-11863 + GAAAAGAGAAAUAAAGCGGCGGA 23 14027 BCL11A-11864 + CGAAAAGAGAAAUAAAGCGGCGGA 24 14028 BCL11A-11865 + UGGGGAAGCGCGGGCGGA 18 14029 BCL11A-11866 + CUGGGGAAGCGCGGGCGGA 19 14030 BCL11A-10048 + GCUGGGGAAGCGCGGGCGGA 20 14031 BCL11A-11867 + GGCUGGGGAAGCGCGGGCGGA 21 14032 BCL11A-11868 + GGGCUGGGGAAGCGCGGGCGGA 22 14033 BCL11A-11869 + CGGGCUGGGGAAGCGCGGGCGGA 23 14034 BCL11A-11870 + CCGGGCUGGGGAAGCGCGGGCGGA 24 14035 BCL11A-11871 + CCAAGGCCGAGCCAGGGA 18 14036 BCL11A-11872 + CCCAAGGCCGAGCCAGGGA 19 14037 BCL11A-11873 + CCCCAAGGCCGAGCCAGGGA 20 14038 BCL11A-11874 + CCCCCAAGGCCGAGCCAGGGA 21 14039 BCL11A-11875 + GCCCCCAAGGCCGAGCCAGGGA 22 14040 BCL11A-11876 + CGCCCCCAAGGCCGAGCCAGGGA 23 14041 BCL11A-11877 + GCGCCCCCAAGGCCGAGCCAGGGA 24 14042 BCL11A-11878 + CGGCCUGGAAAGAGGGGA 18 14043 BCL11A-11879 + GCGGCCUGGAAAGAGGGGA 19 14044 BCL11A-11880 + CGCGGCCUGGAAAGAGGGGA 20 14045 BCL11A-11881 + GCGCGGCCUGGAAAGAGGGGA 21 14046 BCL11A-11882 + CGCGCGGCCUGGAAAGAGGGGA 22 14047 BCL11A-11883 + CCGCGCGGCCUGGAAAGAGGGGA 23 14048 BCL11A-11884 + CCCGCGCGGCCUGGAAAGAGGGGA 24 14049 BCL11A-11885 + UGGCGGGGCGGGGGGGGA 18 14050 BCL11A-11886 + CUGGCGGGGCGGGGGGGGA 19 14051 BCL11A-11887 + ACUGGCGGGGCGGGGGGGGA 20 14052 BCL11A-11888 + AACUGGCGGGGCGGGGGGGGA 21 14053 BCL11A-11889 + AAACUGGCGGGGCGGGGGGGGA 22 14054 BCL11A-11890 + AAAACUGGCGGGGCGGGGGGGGA 23 14055 BCL11A-11891 + CAAAACUGGCGGGGCGGGGGGGGA 24 14056 BCL11A-11892 + GGGCGAGGGGAGGUGGGA 18 14057 BCL11A-11893 + CGGGCGAGGGGAGGUGGGA 19 14058 BCL11A-10052 + GCGGGCGAGGGGAGGUGGGA 20 14059 BCL11A-11894 + AGCGGGCGAGGGGAGGUGGGA 21 14060 BCL11A-11895 + CAGCGGGCGAGGGGAGGUGGGA 22 14061 BCL11A-11896 + GCAGCGGGCGAGGGGAGGUGGGA 23 14062 BCL11A-11897 + CGCAGCGGGCGAGGGGAGGUGGGA 24 14063 BCL11A-11898 + GAGCCCGCGCGGCCUGGA 18 14064 BCL11A-11899 + GGAGCCCGCGCGGCCUGGA 19 14065 BCL11A-11900 + AGGAGCCCGCGCGGCCUGGA 20 14066 BCL11A-11901 + CAGGAGCCCGCGCGGCCUGGA 21 14067 BCL11A-11902 + CCAGGAGCCCGCGCGGCCUGGA 22 14068 BCL11A-11903 + UCCAGGAGCCCGCGCGGCCUGGA 23 14069 BCL11A-11904 + CUCCAGGAGCCCGCGCGGCCUGGA 24 14070 BCL11A-11905 + CCCAUUUUCUUACGGUGA 18 14071 BCL11A-11906 + CCCCAUUUUCUUACGGUGA 19 14072 BCL11A-11907 + CCCCCAUUUUCUUACGGUGA 20 14073 BCL11A-11908 + CCCCCCAUUUUCUUACGGUGA 21 14074 BCL11A-11909 + CCCCCCCAUUUUCUUACGGUGA 22 14075 BCL11A-11910 + ACCCCCCCAUUUUCUUACGGUGA 23 14076 BCL11A-11911 + UACCCCCCCAUUUUCUUACGGUGA 24 14077 BCL11A-11912 + GAGGGAGCGCACGGCAAC 18 14078 BCL11A-11913 + GGAGGGAGCGCACGGCAAC 19 14079 BCL11A-11914 + GGGAGGGAGCGCACGGCAAC 20 14080 BCL11A-11915 + UGGGAGGGAGCGCACGGCAAC 21 14081 BCL11A-11916 + GUGGGAGGGAGCGCACGGCAAC 22 14082 BCL11A-11917 + GGUGGGAGGGAGCGCACGGCAAC 23 14083 BCL11A-11918 + AGGUGGGAGGGAGCGCACGGCAAC 24 14084 BCL11A-10612 + CUGCUCCCCCCCACACAC 18 14085 BCL11A-10613 + CCUGCUCCCCCCCACACAC 19 14086 BCL11A-10614 + CCCUGCUCCCCCCCACACAC 20 14087 BCL11A-10615 + GCCCUGCUCCCCCCCACACAC 21 14088 BCL11A-10616 + CGCCCUGCUCCCCCCCACACAC 22 14089 BCL11A-10617 + GCGCCCUGCUCCCCCCCACACAC 23 14090 BCL11A-10618 + UGCGCCCUGCUCCCCCCCACACAC 24 14091 BCL11A-11919 + AAUAGAGCGAGAGUGCAC 18 14092 BCL11A-11920 + AAAUAGAGCGAGAGUGCAC 19 14093 BCL11A-10059 + AAAAUAGAGCGAGAGUGCAC 20 14094 BCL11A-11921 + AAAAAUAGAGCGAGAGUGCAC 21 14095 BCL11A-11922 + AAAAAAUAGAGCGAGAGUGCAC 22 14096 BCL11A-11923 + AAAAAAAUAGAGCGAGAGUGCAC 23 14097 BCL11A-11924 + GAAAAAAAUAGAGCGAGAGUGCAC 24 14098 BCL11A-11925 + ACAGCAAAGAAAAAUCAC 18 14099 BCL11A-11926 + GACAGCAAAGAAAAAUCAC 19 14100 BCL11A-11927 + GGACAGCAAAGAAAAAUCAC 20 14101 BCL11A-11928 + AGGACAGCAAAGAAAAAUCAC 21 14102 BCL11A-11929 + GAGGACAGCAAAGAAAAAUCAC 22 14103 BCL11A-11930 + AGAGGACAGCAAAGAAAAAUCAC 23 14104 BCL11A-11931 + GAGAGGACAGCAAAGAAAAAUCAC 24 14105 BCL11A-11932 + CAAGGCCGAGCCAGGGAC 18 14106 BCL11A-11933 + CCAAGGCCGAGCCAGGGAC 19 14107 BCL11A-10063 + CCCAAGGCCGAGCCAGGGAC 20 14108 BCL11A-11934 + CCCCAAGGCCGAGCCAGGGAC 21 14109 BCL11A-11935 + CCCCCAAGGCCGAGCCAGGGAC 22 14110 BCL11A-11936 + GCCCCCAAGGCCGAGCCAGGGAC 23 14111 BCL11A-11937 + CGCCCCCAAGGCCGAGCCAGGGAC 24 14112 BCL11A-11938 + GGCCUGGAAAGAGGGGAC 18 14113 BCL11A-11939 + CGGCCUGGAAAGAGGGGAC 19 14114 BCL11A-10064 + GCGGCCUGGAAAGAGGGGAC 20 14115 BCL11A-11940 + CGCGGCCUGGAAAGAGGGGAC 21 14116 BCL11A-11941 + GCGCGGCCUGGAAAGAGGGGAC 22 14117 BCL11A-11942 + CGCGCGGCCUGGAAAGAGGGGAC 23 14118 BCL11A-11943 + CCGCGCGGCCUGGAAAGAGGGGAC 24 14119 BCL11A-11944 + AUAGAGCGAGAGUGCACC 18 14120 BCL11A-11945 + AAUAGAGCGAGAGUGCACC 19 14121 BCL11A-10067 + AAAUAGAGCGAGAGUGCACC 20 14122 BCL11A-11946 + AAAAUAGAGCGAGAGUGCACC 21 14123 BCL11A-11947 + AAAAAUAGAGCGAGAGUGCACC 22 14124 BCL11A-11948 + AAAAAAUAGAGCGAGAGUGCACC 23 14125 BCL11A-11949 + AAAAAAAUAGAGCGAGAGUGCACC 24 14126 BCL11A-11950 + AAGGCCGAGCCAGGGACC 18 14127 BCL11A-11951 + CAAGGCCGAGCCAGGGACC 19 14128 BCL11A-10068 + CCAAGGCCGAGCCAGGGACC 20 14129 BCL11A-11952 + CCCAAGGCCGAGCCAGGGACC 21 14130 BCL11A-11953 + CCCCAAGGCCGAGCCAGGGACC 22 14131 BCL11A-11954 + CCCCCAAGGCCGAGCCAGGGACC 23 14132 BCL11A-11955 + GCCCCCAAGGCCGAGCCAGGGACC 24 14133 BCL11A-11956 + GCCUGGAAAGAGGGGACC 18 14134 BCL11A-11957 + GGCCUGGAAAGAGGGGACC 19 14135 BCL11A-10069 + CGGCCUGGAAAGAGGGGACC 20 14136 BCL11A-11958 + GCGGCCUGGAAAGAGGGGACC 21 14137 BCL11A-11959 + CGCGGCCUGGAAAGAGGGGACC 22 14138 BCL11A-11960 + GCGCGGCCUGGAAAGAGGGGACC 23 14139 BCL11A-11961 + CGCGCGGCCUGGAAAGAGGGGACC 24 14140 BCL11A-11962 + CCCGCUGCACACUUGACC 18 14141 BCL11A-11963 + UCCCGCUGCACACUUGACC 19 14142 BCL11A-11964 + CUCCCGCUGCACACUUGACC 20 14143 BCL11A-11965 + CCUCCCGCUGCACACUUGACC 21 14144 BCL11A-11966 + UCCUCCCGCUGCACACUUGACC 22 14145 BCL11A-11967 + UUCCUCCCGCUGCACACUUGACC 23 14146 BCL11A-11968 + UUUCCUCCCGCUGCACACUUGACC 24 14147 BCL11A-11969 + CGGCGCAGGCCGGGGCCC 18 14148 BCL11A-11970 + GCGGCGCAGGCCGGGGCCC 19 14149 BCL11A-11971 + GGCGGCGCAGGCCGGGGCCC 20 14150 BCL11A-11972 + AGGCGGCGCAGGCCGGGGCCC 21 14151 BCL11A-11973 + CAGGCGGCGCAGGCCGGGGCCC 22 14152 BCL11A-11974 + GCAGGCGGCGCAGGCCGGGGCCC 23 14153 BCL11A-11975 + GGCAGGCGGCGCAGGCCGGGGCCC 24 14154 BCL11A-11976 + GCUCGGGAAACUUUGCCC 18 14155 BCL11A-11977 + CGCUCGGGAAACUUUGCCC 19 14156 BCL11A-11978 + GCGCUCGGGAAACUUUGCCC 20 14157 BCL11A-11979 + UGCGCUCGGGAAACUUUGCCC 21 14158 BCL11A-11980 + CUGCGCUCGGGAAACUUUGCCC 22 14159 BCL11A-11981 + GCUGCGCUCGGGAAACUUUGCCC 23 14160 BCL11A-11982 + GGCUGCGCUCGGGAAACUUUGCCC 24 14161 BCL11A-11983 + UCUCACCUCUUUUCUCCC 18 14162 BCL11A-11984 + GUCUCACCUCUUUUCUCCC 19 14163 BCL11A-10081 + AGUCUCACCUCUUUUCUCCC 20 14164 BCL11A-11985 + CAGUCUCACCUCUUUUCUCCC 21 14165 BCL11A-11986 + CCAGUCUCACCUCUUUUCUCCC 22 14166 BCL11A-11987 + GCCAGUCUCACCUCUUUUCUCCC 23 14167 BCL11A-11988 + AGCCAGUCUCACCUCUUUUCUCCC 24 14168 BCL11A-11989 + GGGGCCGAAGUAAAAGCC 18 14169 BCL11A-11990 + AGGGGCCGAAGUAAAAGCC 19 14170 BCL11A-11991 + CAGGGGCCGAAGUAAAAGCC 20 14171 BCL11A-11992 + CCAGGGGCCGAAGUAAAAGCC 21 14172 BCL11A-11993 + GCCAGGGGCCGAAGUAAAAGCC 22 14173 BCL11A-11994 + CGCCAGGGGCCGAAGUAAAAGCC 23 14174 BCL11A-11995 + ACGCCAGGGGCCGAAGUAAAAGCC 24 14175 BCL11A-11996 + CACCGGGAGGCUGCAGCC 18 14176 BCL11A-11997 + GCACCGGGAGGCUGCAGCC 19 14177 BCL11A-11998 + UGCACCGGGAGGCUGCAGCC 20 14178 BCL11A-11999 + GUGCACCGGGAGGCUGCAGCC 21 14179 BCL11A-12000 + AGUGCACCGGGAGGCUGCAGCC 22 14180 BCL11A-12001 + GAGUGCACCGGGAGGCUGCAGCC 23 14181 BCL11A-12002 + AGAGUGCACCGGGAGGCUGCAGCC 24 14182 BCL11A-12003 + CGCCCCCAAGGCCGAGCC 18 14183 BCL11A-12004 + GCGCCCCCAAGGCCGAGCC 19 14184 BCL11A-10085 + GGCGCCCCCAAGGCCGAGCC 20 14185 BCL11A-12005 + GGGCGCCCCCAAGGCCGAGCC 21 14186 BCL11A-12006 + AGGGCGCCCCCAAGGCCGAGCC 22 14187 BCL11A-12007 + GAGGGCGCCCCCAAGGCCGAGCC 23 14188 BCL11A-12008 + CGAGGGCGCCCCCAAGGCCGAGCC 24 14189 BCL11A-12009 + UCCCCGCGUGUGGACGCC 18 14190 BCL11A-12010 + CUCCCCGCGUGUGGACGCC 19 14191 BCL11A-10086 + GCUCCCCGCGUGUGGACGCC 20 14192 BCL11A-12011 + CGCUCCCCGCGUGUGGACGCC 21 14193 BCL11A-12012 + UCGCUCCCCGCGUGUGGACGCC 22 14194 BCL11A-12013 + CUCGCUCCCCGCGUGUGGACGCC 23 14195 BCL11A-12014 + GCUCGCUCCCCGCGUGUGGACGCC 24 14196 BCL11A-12015 + CGCGGACUCAGGAGCGCC 18 14197 BCL11A-12016 + CCGCGGACUCAGGAGCGCC 19 14198 BCL11A-10087 + UCCGCGGACUCAGGAGCGCC 20 14199 BCL11A-12017 + CUCCGCGGACUCAGGAGCGCC 21 14200 BCL11A-12018 + ACUCCGCGGACUCAGGAGCGCC 22 14201 BCL11A-12019 + GACUCCGCGGACUCAGGAGCGCC 23 14202 BCL11A-12020 + CGACUCCGCGGACUCAGGAGCGCC 24 14203 BCL11A-12021 + CCAGGAGCCCGCGCGGCC 18 14204 BCL11A-12022 + UCCAGGAGCCCGCGCGGCC 19 14205 BCL11A-10089 + CUCCAGGAGCCCGCGCGGCC 20 14206 BCL11A-12023 + UCUCCAGGAGCCCGCGCGGCC 21 14207 BCL11A-12024 + GUCUCCAGGAGCCCGCGCGGCC 22 14208 BCL11A-12025 + AGUCUCCAGGAGCCCGCGCGGCC 23 14209 BCL11A-12026 + AAGUCUCCAGGAGCCCGCGCGGCC 24 14210 BCL11A-12027 + GGCCCCUCUCCCGACUCC 18 14211 BCL11A-12028 + CGGCCCCUCUCCCGACUCC 19 14212 BCL11A-12029 + GCGGCCCCUCUCCCGACUCC 20 14213 BCL11A-12030 + CGCGGCCCCUCUCCCGACUCC 21 14214 BCL11A-12031 + CCGCGGCCCCUCUCCCGACUCC 22 14215 BCL11A-12032 + GCCGCGGCCCCUCUCCCGACUCC 23 14216 BCL11A-12033 + CGCCGCGGCCCCUCUCCCGACUCC 24 14217 BCL11A-12034 + GGCAGCGCCCAAGUCUCC 18 14218 BCL11A-12035 + GGGCAGCGCCCAAGUCUCC 19 14219 BCL11A-10093 + AGGGCAGCGCCCAAGUCUCC 20 14220 BCL11A-12036 + AAGGGCAGCGCCCAAGUCUCC 21 14221 BCL11A-12037 + GAAGGGCAGCGCCCAAGUCUCC 22 14222 BCL11A-12038 + GGAAGGGCAGCGCCCAAGUCUCC 23 14223 BCL11A-12039 + CGGAAGGGCAGCGCCCAAGUCUCC 24 14224 BCL11A-12040 + GUCUCACCUCUUUUCUCC 18 14225 BCL11A-12041 + AGUCUCACCUCUUUUCUCC 19 14226 BCL11A-12042 + CAGUCUCACCUCUUUUCUCC 20 14227 BCL11A-12043 + CCAGUCUCACCUCUUUUCUCC 21 14228 BCL11A-12044 + GCCAGUCUCACCUCUUUUCUCC 22 14229 BCL11A-12045 + AGCCAGUCUCACCUCUUUUCUCC 23 14230 BCL11A-12046 + AAGCCAGUCUCACCUCUUUUCUCC 24 14231 BCL11A-12047 + CGGCGCGGGAGGGCAAGC 18 14232 BCL11A-12048 + GCGGCGCGGGAGGGCAAGC 19 14233 BCL11A-12049 + GGCGGCGCGGGAGGGCAAGC 20 14234 BCL11A-12050 + GCCCCGGGCUGGGGAAGC 18 14235 BCL11A-12051 + AGCCCCGGGCUGGGGAAGC 19 14236 BCL11A-12052 + CAGCCCCGGGCUGGGGAAGC 20 14237 BCL11A-12053 + GCAGCCCCGGGCUGGGGAAGC 21 14238 BCL11A-12054 + UGCAGCCCCGGGCUGGGGAAGC 22 14239 BCL11A-12055 + CUGCAGCCCCGGGCUGGGGAAGC 23 14240 BCL11A-12056 + GCUGCAGCCCCGGGCUGGGGAAGC 24 14241 BCL11A-12057 + GCGCCCCCAAGGCCGAGC 18 14242 BCL11A-12058 + GGCGCCCCCAAGGCCGAGC 19 14243 BCL11A-12059 + GGGCGCCCCCAAGGCCGAGC 20 14244 BCL11A-12060 + AGGGCGCCCCCAAGGCCGAGC 21 14245 BCL11A-12061 + GAGGGCGCCCCCAAGGCCGAGC 22 14246 BCL11A-12062 + CGAGGGCGCCCCCAAGGCCGAGC 23 14247 BCL11A-12063 + CCGAGGGCGCCCCCAAGGCCGAGC 24 14248 BCL11A-12064 + CUCCCCGCGUGUGGACGC 18 14249 BCL11A-12065 + GCUCCCCGCGUGUGGACGC 19 14250 BCL11A-12066 + CGCUCCCCGCGUGUGGACGC 20 14251 BCL11A-12067 + UCGCUCCCCGCGUGUGGACGC 21 14252 BCL11A-12068 + CUCGCUCCCCGCGUGUGGACGC 22 14253 BCL11A-12069 + GCUCGCUCCCCGCGUGUGGACGC 23 14254 BCL11A-12070 + CGCUCGCUCCCCGCGUGUGGACGC 24 14255 BCL11A-12071 + GCGCGGGAGGGCAAGCGC 18 14256 BCL11A-12072 + GGCGCGGGAGGGCAAGCGC 19 14257 BCL11A-12073 + CGGCGCGGGAGGGCAAGCGC 20 14258 BCL11A-12074 + CCGCGGACUCAGGAGCGC 18 14259 BCL11A-12075 + UCCGCGGACUCAGGAGCGC 19 14260 BCL11A-10106 + CUCCGCGGACUCAGGAGCGC 20 14261 BCL11A-12076 + ACUCCGCGGACUCAGGAGCGC 21 14262 BCL11A-12077 + GACUCCGCGGACUCAGGAGCGC 22 14263 BCL11A-12078 + CGACUCCGCGGACUCAGGAGCGC 23 14264 BCL11A-12079 + CCGACUCCGCGGACUCAGGAGCGC 24 14265 BCL11A-12080 + CCGAGCCCGCGGCUGCGC 18 14266 BCL11A-12081 + CCCGAGCCCGCGGCUGCGC 19 14267 BCL11A-12082 + CCCCGAGCCCGCGGCUGCGC 20 14268 BCL11A-12083 + GCCCCGAGCCCGCGGCUGCGC 21 14269 BCL11A-12084 + AGCCCCGAGCCCGCGGCUGCGC 22 14270 BCL11A-12085 + AAGCCCCGAGCCCGCGGCUGCGC 23 14271 BCL11A-12086 + AAAGCCCCGAGCCCGCGGCUGCGC 24 14272 BCL11A-12087 + GAGGCAGGCGGCGCAGGC 18 14273 BCL11A-12088 + AGAGGCAGGCGGCGCAGGC 19 14274 BCL11A-10110 + GAGAGGCAGGCGGCGCAGGC 20 14275 BCL11A-12089 + GGAGAGGCAGGCGGCGCAGGC 21 14276 BCL11A-12090 + GGGAGAGGCAGGCGGCGCAGGC 22 14277 BCL11A-12091 + GGGGAGAGGCAGGCGGCGCAGGC 23 14278 BCL11A-12092 + CGGGGAGAGGCAGGCGGCGCAGGC 24 14279 BCL11A-12093 + UCCAGGAGCCCGCGCGGC 18 14280 BCL11A-12094 + CUCCAGGAGCCCGCGCGGC 19 14281 BCL11A-12095 + UCUCCAGGAGCCCGCGCGGC 20 14282 BCL11A-12096 + GUCUCCAGGAGCCCGCGCGGC 21 14283 BCL11A-12097 + AGUCUCCAGGAGCCCGCGCGGC 22 14284 BCL11A-12098 + AAGUCUCCAGGAGCCCGCGCGGC 23 14285 BCL11A-12099 + CAAGUCUCCAGGAGCCCGCGCGGC 24 14286 BCL11A-12100 + GAGGCUGCAGCCCCGGGC 18 14287 BCL11A-12101 + GGAGGCUGCAGCCCCGGGC 19 14288 BCL11A-10115 + GGGAGGCUGCAGCCCCGGGC 20 14289 BCL11A-12102 + CGGGAGGCUGCAGCCCCGGGC 21 14290 BCL11A-12103 + CCGGGAGGCUGCAGCCCCGGGC 22 14291 BCL11A-12104 + ACCGGGAGGCUGCAGCCCCGGGC 23 14292 BCL11A-12105 + CACCGGGAGGCUGCAGCCCCGGGC 24 14293 BCL11A-12106 + UACAGCUCCGCAGCGGGC 18 14294 BCL11A-12107 + UUACAGCUCCGCAGCGGGC 19 14295 BCL11A-12108 + GUUACAGCUCCGCAGCGGGC 20 14296 BCL11A-12109 + AGUUACAGCUCCGCAGCGGGC 21 14297 BCL11A-12110 + AAGUUACAGCUCCGCAGCGGGC 22 14298 BCL11A-12111 + CAAGUUACAGCUCCGCAGCGGGC 23 14299 BCL11A-12112 + CCAAGUUACAGCUCCGCAGCGGGC 24 14300 BCL11A-12113 + GGCGGCGCAGGCCGGGGC 18 14301 BCL11A-12114 + AGGCGGCGCAGGCCGGGGC 19 14302 BCL11A-12115 + CAGGCGGCGCAGGCCGGGGC 20 14303 BCL11A-12116 + GCAGGCGGCGCAGGCCGGGGC 21 14304 BCL11A-12117 + GGCAGGCGGCGCAGGCCGGGGC 22 14305 BCL11A-12118 + AGGCAGGCGGCGCAGGCCGGGGC 23 14306 BCL11A-12119 + GAGGCAGGCGGCGCAGGCCGGGGC 24 14307 BCL11A-12120 + UUGCAAAACUGGCGGGGC 18 14308 BCL11A-12121 + UUUGCAAAACUGGCGGGGC 19 14309 BCL11A-10116 + UUUUGCAAAACUGGCGGGGC 20 14310 BCL11A-12122 + AUUUUGCAAAACUGGCGGGGC 21 14311 BCL11A-12123 + UAUUUUGCAAAACUGGCGGGGC 22 14312 BCL11A-12124 + UUAUUUUGCAAAACUGGCGGGGC 23 14313 BCL11A-12125 + AUUAUUUUGCAAAACUGGCGGGGC 24 14314 BCL11A-12126 + CAAACACCCACCUCUGGC 18 14315 BCL11A-12127 + ACAAACACCCACCUCUGGC 19 14316 BCL11A-10118 + GACAAACACCCACCUCUGGC 20 14317 BCL11A-12128 + GGACAAACACCCACCUCUGGC 21 14318 BCL11A-12129 + GGGACAAACACCCACCUCUGGC 22 14319 BCL11A-12130 + CGGGACAAACACCCACCUCUGGC 23 14320 BCL11A-12131 + GCGGGACAAACACCCACCUCUGGC 24 14321 BCL11A-12132 + GCGCUCGGGAAACUUUGC 18 14322 BCL11A-12133 + UGCGCUCGGGAAACUUUGC 19 14323 BCL11A-12134 + CUGCGCUCGGGAAACUUUGC 20 14324 BCL11A-12135 + GCUGCGCUCGGGAAACUUUGC 21 14325 BCL11A-12136 + GGCUGCGCUCGGGAAACUUUGC 22 14326 BCL11A-12137 + CGGCUGCGCUCGGGAAACUUUGC 23 14327 BCL11A-12138 + GCGGCUGCGCUCGGGAAACUUUGC 24 14328 BCL11A-12139 + UCCCGACUCCGCGGACUC 18 14329 BCL11A-12140 + CUCCCGACUCCGCGGACUC 19 14330 BCL11A-10122 + UCUCCCGACUCCGCGGACUC 20 14331 BCL11A-12141 + CUCUCCCGACUCCGCGGACUC 21 14332 BCL11A-12142 + CCUCUCCCGACUCCGCGGACUC 22 14333 BCL11A-12143 + CCCUCUCCCGACUCCGCGGACUC 23 14334 BCL11A-12144 + CCCCUCUCCCGACUCCGCGGACUC 24 14335 BCL11A-12145 + GAGCCCGCGGCUGCGCUC 18 14336 BCL11A-12146 + CGAGCCCGCGGCUGCGCUC 19 14337 BCL11A-10126 + CCGAGCCCGCGGCUGCGCUC 20 14338 BCL11A-12147 + CCCGAGCCCGCGGCUGCGCUC 21 14339 BCL11A-12148 + CCCCGAGCCCGCGGCUGCGCUC 22 14340 BCL11A-12149 + GCCCCGAGCCCGCGGCUGCGCUC 23 14341 BCL11A-12150 + AGCCCCGAGCCCGCGGCUGCGCUC 24 14342 BCL11A-12151 + AGCCAGGUAGAGUUGCUC 18 14343 BCL11A-12152 + AAGCCAGGUAGAGUUGCUC 19 14344 BCL11A-12153 + GAAGCCAGGUAGAGUUGCUC 20 14345 BCL11A-12154 + GGAAGCCAGGUAGAGUUGCUC 21 14346 BCL11A-12155 + GGGAAGCCAGGUAGAGUUGCUC 22 14347 BCL11A-12156 + AGGGAAGCCAGGUAGAGUUGCUC 23 14348 BCL11A-12157 + GAGGGAAGCCAGGUAGAGUUGCUC 24 14349 BCL11A-12158 + GGGCAGCGCCCAAGUCUC 18 14350 BCL11A-12159 + AGGGCAGCGCCCAAGUCUC 19 14351 BCL11A-12160 + AAGGGCAGCGCCCAAGUCUC 20 14352 BCL11A-12161 + GAAGGGCAGCGCCCAAGUCUC 21 14353 BCL11A-12162 + GGAAGGGCAGCGCCCAAGUCUC 22 14354 BCL11A-12163 + CGGAAGGGCAGCGCCCAAGUCUC 23 14355 BCL11A-12164 + CCGGAAGGGCAGCGCCCAAGUCUC 24 14356 BCL11A-12165 + UUUGGAGGGCUGCGGGUC 18 14357 BCL11A-12166 + GUUUGGAGGGCUGCGGGUC 19 14358 BCL11A-10129 + AGUUUGGAGGGCUGCGGGUC 20 14359 BCL11A-12167 + AAGUUUGGAGGGCUGCGGGUC 21 14360 BCL11A-12168 + UAAGUUUGGAGGGCUGCGGGUC 22 14361 BCL11A-12169 + CUAAGUUUGGAGGGCUGCGGGUC 23 14362 BCL11A-12170 + CCUAAGUUUGGAGGGCUGCGGGUC 24 14363 BCL11A-12171 + CGGCGGAAAGGAGGAAAG 18 14364 BCL11A-12172 + GCGGCGGAAAGGAGGAAAG 19 14365 BCL11A-10136 + AGCGGCGGAAAGGAGGAAAG 20 14366 BCL11A-12173 + AAGCGGCGGAAAGGAGGAAAG 21 14367 BCL11A-12174 + AAAGCGGCGGAAAGGAGGAAAG 22 14368 BCL11A-12175 + UAAAGCGGCGGAAAGGAGGAAAG 23 14369 BCL11A-12176 + AUAAAGCGGCGGAAAGGAGGAAAG 24 14370 BCL11A-12177 + AAAUAAAGCGGCGGAAAG 18 14371 BCL11A-12178 + GAAAUAAAGCGGCGGAAAG 19 14372 BCL11A-12179 + AGAAAUAAAGCGGCGGAAAG 20 14373 BCL11A-12180 + GAGAAAUAAAGCGGCGGAAAG 21 14374 BCL11A-12181 + AGAGAAAUAAAGCGGCGGAAAG 22 14375 BCL11A-12182 + AAGAGAAAUAAAGCGGCGGAAAG 23 14376 BCL11A-12183 + AAAGAGAAAUAAAGCGGCGGAAAG 24 14377 BCL11A-12184 + CCCGCGCGGCCUGGAAAG 18 14378 BCL11A-12185 + GCCCGCGCGGCCUGGAAAG 19 14379 BCL11A-10137 + AGCCCGCGCGGCCUGGAAAG 20 14380 BCL11A-12186 + GAGCCCGCGCGGCCUGGAAAG 21 14381 BCL11A-12187 + GGAGCCCGCGCGGCCUGGAAAG 22 14382 BCL11A-12188 + AGGAGCCCGCGCGGCCUGGAAAG 23 14383 BCL11A-12189 + CAGGAGCCCGCGCGGCCUGGAAAG 24 14384 BCL11A-12190 + AAGAAAAAUCACCCGAAG 18 14385 BCL11A-12191 + AAAGAAAAAUCACCCGAAG 19 14386 BCL11A-12192 + CAAAGAAAAAUCACCCGAAG 20 14387 BCL11A-12193 + GCAAAGAAAAAUCACCCGAAG 21 14388 BCL11A-12194 + AGCAAAGAAAAAUCACCCGAAG 22 14389 BCL11A-12195 + CAGCAAAGAAAAAUCACCCGAAG 23 14390 BCL11A-12196 + ACAGCAAAGAAAAAUCACCCGAAG 24 14391 BCL11A-12197 + AGCCGGCACAAAAGGCAG 18 14392 BCL11A-12198 + GAGCCGGCACAAAAGGCAG 19 14393 BCL11A-10144 + GGAGCCGGCACAAAAGGCAG 20 14394 BCL11A-12199 + AGGAGCCGGCACAAAAGGCAG 21 14395 BCL11A-12200 + GAGGAGCCGGCACAAAAGGCAG 22 14396 BCL11A-12201 + CGAGGAGCCGGCACAAAAGGCAG 23 14397 BCL11A-12202 + GCGAGGAGCCGGCACAAAAGGCAG 24 14398 BCL11A-12203 + GCGGAAAGGAGGAAAGAG 18 14399 BCL11A-12204 + GGCGGAAAGGAGGAAAGAG 19 14400 BCL11A-12205 + CGGCGGAAAGGAGGAAAGAG 20 14401 BCL11A-12206 + GCGGCGGAAAGGAGGAAAGAG 21 14402 BCL11A-12207 + AGCGGCGGAAAGGAGGAAAGAG 22 14403 BCL11A-12208 + AAGCGGCGGAAAGGAGGAAAGAG 23 14404 BCL11A-12209 + AAAGCGGCGGAAAGGAGGAAAGAG 24 14405 BCL11A-12210 + AUCACCCGAAGUUGAGAG 18 14406 BCL11A-12211 + AAUCACCCGAAGUUGAGAG 19 14407 BCL11A-12212 + AAAUCACCCGAAGUUGAGAG 20 14408 BCL11A-12213 + AAAAUCACCCGAAGUUGAGAG 21 14409 BCL11A-12214 + AAAAAUCACCCGAAGUUGAGAG 22 14410 BCL11A-12215 + GAAAAAUCACCCGAAGUUGAGAG 23 14411 BCL11A-12216 + AGAAAAAUCACCCGAAGUUGAGAG 24 14412 BCL11A-12217 + CGGGAAACUUUGCCCGAG 18 14413 BCL11A-12218 + UCGGGAAACUUUGCCCGAG 19 14414 BCL11A-12219 + CUCGGGAAACUUUGCCCGAG 20 14415 BCL11A-12220 + GCUCGGGAAACUUUGCCCGAG 21 14416 BCL11A-12221 + CGCUCGGGAAACUUUGCCCGAG 22 14417 BCL11A-12222 + GCGCUCGGGAAACUUUGCCCGAG 23 14418 BCL11A-12223 + UGCGCUCGGGAAACUUUGCCCGAG 24 14419 BCL11A-12224 + AGCUCCGCAGCGGGCGAG 18 14420 BCL11A-12225 + CAGCUCCGCAGCGGGCGAG 19 14421 BCL11A-10148 + ACAGCUCCGCAGCGGGCGAG 20 14422 BCL11A-12226 + UACAGCUCCGCAGCGGGCGAG 21 14423 BCL11A-12227 + UUACAGCUCCGCAGCGGGCGAG 22 14424 BCL11A-12228 + GUUACAGCUCCGCAGCGGGCGAG 23 14425 BCL11A-12229 + AGUUACAGCUCCGCAGCGGGCGAG 24 14426 BCL11A-12230 + CGCAGCGGGCGAGGGGAG 18 14427 BCL11A-12231 + CCGCAGCGGGCGAGGGGAG 19 14428 BCL11A-12232 + UCCGCAGCGGGCGAGGGGAG 20 14429 BCL11A-12233 + CUCCGCAGCGGGCGAGGGGAG 21 14430 BCL11A-12234 + GCUCCGCAGCGGGCGAGGGGAG 22 14431 BCL11A-12235 + AGCUCCGCAGCGGGCGAGGGGAG 23 14432 BCL11A-12236 + CAGCUCCGCAGCGGGCGAGGGGAG 24 14433 BCL11A-12237 + CCAUUUUCUUACGGUGAG 18 14434 BCL11A-12238 + CCCAUUUUCUUACGGUGAG 19 14435 BCL11A-10154 + CCCCAUUUUCUUACGGUGAG 20 14436 BCL11A-12239 + CCCCCAUUUUCUUACGGUGAG 21 14437 BCL11A-12240 + CCCCCCAUUUUCUUACGGUGAG 22 14438 BCL11A-12241 + CCCCCCCAUUUUCUUACGGUGAG 23 14439 BCL11A-12242 + ACCCCCCCAUUUUCUUACGGUGAG 24 14440 BCL11A-12243 + CCUGGAAAGAGGGGACCG 18 14441 BCL11A-12244 + GCCUGGAAAGAGGGGACCG 19 14442 BCL11A-10159 + GGCCUGGAAAGAGGGGACCG 20 14443 BCL11A-12245 + CGGCCUGGAAAGAGGGGACCG 21 14444 BCL11A-12246 + GCGGCCUGGAAAGAGGGGACCG 22 14445 BCL11A-12247 + CGCGGCCUGGAAAGAGGGGACCG 23 14446 BCL11A-12248 + GCGCGGCCUGGAAAGAGGGGACCG 24 14447 BCL11A-12249 + CUCGGGAAACUUUGCCCG 18 14448 BCL11A-12250 + GCUCGGGAAACUUUGCCCG 19 14449 BCL11A-10163 + CGCUCGGGAAACUUUGCCCG 20 14450 BCL11A-12251 + GCGCUCGGGAAACUUUGCCCG 21 14451 BCL11A-12252 + UGCGCUCGGGAAACUUUGCCCG 22 14452 BCL11A-12253 + CUGCGCUCGGGAAACUUUGCCCG 23 14453 BCL11A-12254 + GCUGCGCUCGGGAAACUUUGCCCG 24 14454 BCL11A-12255 + GAAAAGAGAAAUAAAGCG 18 14455 BCL11A-12256 + CGAAAAGAGAAAUAAAGCG 19 14456 BCL11A-12257 + UCGAAAAGAGAAAUAAAGCG 20 14457 BCL11A-12258 + UUCGAAAAGAGAAAUAAAGCG 21 14458 BCL11A-12259 + UUUCGAAAAGAGAAAUAAAGCG 22 14459 BCL11A-12260 + UUUUCGAAAAGAGAAAUAAAGCG 23 14460 BCL11A-12261 + CUUUUCGAAAAGAGAAAUAAAGCG 24 14461 BCL11A-12262 + UCCGCGGACUCAGGAGCG 18 14462 BCL11A-12263 + CUCCGCGGACUCAGGAGCG 19 14463 BCL11A-12264 + ACUCCGCGGACUCAGGAGCG 20 14464 BCL11A-12265 + GACUCCGCGGACUCAGGAGCG 21 14465 BCL11A-12266 + CGACUCCGCGGACUCAGGAGCG 22 14466 BCL11A-12267 + CCGACUCCGCGGACUCAGGAGCG 23 14467 BCL11A-12268 + CCCGACUCCGCGGACUCAGGAGCG 24 14468 BCL11A-12269 + CGCGGGAGGGCAAGCGCG 18 14469 BCL11A-12270 + GCGCGGGAGGGCAAGCGCG 19 14470 BCL11A-10178 + GGCGCGGGAGGGCAAGCGCG 20 14471 BCL11A-12271 + ACAGCUCCGCAGCGGGCG 18 14472 BCL11A-12272 + UACAGCUCCGCAGCGGGCG 19 14473 BCL11A-10180 + UUACAGCUCCGCAGCGGGCG 20 14474 BCL11A-12273 + GUUACAGCUCCGCAGCGGGCG 21 14475 BCL11A-12274 + AGUUACAGCUCCGCAGCGGGCG 22 14476 BCL11A-12275 + AAGUUACAGCUCCGCAGCGGGCG 23 14477 BCL11A-12276 + CAAGUUACAGCUCCGCAGCGGGCG 24 14478 BCL11A-12277 + GCUGGGGAAGCGCGGGCG 18 14479 BCL11A-12278 + GGCUGGGGAAGCGCGGGCG 19 14480 BCL11A-12279 + GGGCUGGGGAAGCGCGGGCG 20 14481 BCL11A-12280 + CGGGCUGGGGAAGCGCGGGCG 21 14482 BCL11A-12281 + CCGGGCUGGGGAAGCGCGGGCG 22 14483 BCL11A-12282 + CCCGGGCUGGGGAAGCGCGGGCG 23 14484 BCL11A-12283 + CCCCGGGCUGGGGAAGCGCGGGCG 24 14485 BCL11A-12284 + UGCAAAACUGGCGGGGCG 18 14486 BCL11A-12285 + UUGCAAAACUGGCGGGGCG 19 14487 BCL11A-10181 + UUUGCAAAACUGGCGGGGCG 20 14488 BCL11A-12286 + UUUUGCAAAACUGGCGGGGCG 21 14489 BCL11A-12287 + AUUUUGCAAAACUGGCGGGGCG 22 14490 BCL11A-12288 + UAUUUUGCAAAACUGGCGGGGCG 23 14491 BCL11A-12289 + UUAUUUUGCAAAACUGGCGGGGCG 24 14492 BCL11A-12290 + AAUAAAGCGGCGGAAAGG 18 14493 BCL11A-12291 + AAAUAAAGCGGCGGAAAGG 19 14494 BCL11A-10185 + GAAAUAAAGCGGCGGAAAGG 20 14495 BCL11A-12292 + AGAAAUAAAGCGGCGGAAAGG 21 14496 BCL11A-12293 + GAGAAAUAAAGCGGCGGAAAGG 22 14497 BCL11A-12294 + AGAGAAAUAAAGCGGCGGAAAGG 23 14498 BCL11A-12295 + AAGAGAAAUAAAGCGGCGGAAAGG 24 14499 BCL11A-12296 + CCGAGGGCGCCCCCAAGG 18 14500 BCL11A-12297 + CCCGAGGGCGCCCCCAAGG 19 14501 BCL11A-12298 + GCCCGAGGGCGCCCCCAAGG 20 14502 BCL11A-12299 + GGCCCGAGGGCGCCCCCAAGG 21 14503 BCL11A-12300 + GGGCCCGAGGGCGCCCCCAAGG 22 14504 BCL11A-12301 + GGGGCCCGAGGGCGCCCCCAAGG 23 14505 BCL11A-12302 + CGGGGCCCGAGGGCGCCCCCAAGG 24 14506 BCL11A-12303 + AGAGGCAGGCGGCGCAGG 18 14507 BCL11A-12304 + GAGAGGCAGGCGGCGCAGG 19 14508 BCL11A-12305 + GGAGAGGCAGGCGGCGCAGG 20 14509 BCL11A-12306 + GGGAGAGGCAGGCGGCGCAGG 21 14510 BCL11A-12307 + GGGGAGAGGCAGGCGGCGCAGG 22 14511 BCL11A-12308 + CGGGGAGAGGCAGGCGGCGCAGG 23 14512 BCL11A-12309 + CCGGGGAGAGGCAGGCGGCGCAGG 24 14513 BCL11A-12310 + GCAGCGGGCGAGGGGAGG 18 14514 BCL11A-12311 + CGCAGCGGGCGAGGGGAGG 19 14515 BCL11A-10190 + CCGCAGCGGGCGAGGGGAGG 20 14516 BCL11A-12312 + UCCGCAGCGGGCGAGGGGAGG 21 14517 BCL11A-12313 + CUCCGCAGCGGGCGAGGGGAGG 22 14518 BCL11A-12314 + GCUCCGCAGCGGGCGAGGGGAGG 23 14519 BCL11A-12315 + AGCUCCGCAGCGGGCGAGGGGAGG 24 14520 BCL11A-12316 + GGAGGGCUGCGGGUCCGG 18 14521 BCL11A-12317 + UGGAGGGCUGCGGGUCCGG 19 14522 BCL11A-12318 + UUGGAGGGCUGCGGGUCCGG 20 14523 BCL11A-12319 + UUUGGAGGGCUGCGGGUCCGG 21 14524 BCL11A-12320 + GUUUGGAGGGCUGCGGGUCCGG 22 14525 BCL11A-12321 + AGUUUGGAGGGCUGCGGGUCCGG 23 14526 BCL11A-12322 + AAGUUUGGAGGGCUGCGGGUCCGG 24 14527 BCL11A-12323 + AAAAGAGAAAUAAAGCGG 18 14528 BCL11A-12324 + GAAAAGAGAAAUAAAGCGG 19 14529 BCL11A-10193 + CGAAAAGAGAAAUAAAGCGG 20 14530 BCL11A-12325 + UCGAAAAGAGAAAUAAAGCGG 21 14531 BCL11A-12326 + UUCGAAAAGAGAAAUAAAGCGG 22 14532 BCL11A-12327 + UUUCGAAAAGAGAAAUAAAGCGG 23 14533 BCL11A-12328 + UUUUCGAAAAGAGAAAUAAAGCGG 24 14534 BCL11A-12329 + GUUACAGCUCCGCAGCGG 18 14535 BCL11A-12330 + AGUUACAGCUCCGCAGCGG 19 14536 BCL11A-12331 + AAGUUACAGCUCCGCAGCGG 20 14537 BCL11A-12332 + CAAGUUACAGCUCCGCAGCGG 21 14538 BCL11A-12333 + CCAAGUUACAGCUCCGCAGCGG 22 14539 BCL11A-12334 + UCCAAGUUACAGCUCCGCAGCGG 23 14540 BCL11A-12335 + CUCCAAGUUACAGCUCCGCAGCGG 24 14541 BCL11A-12336 + CGGGCUGGGGAAGCGCGG 18 14542 BCL11A-12337 + CCGGGCUGGGGAAGCGCGG 19 14543 BCL11A-12338 + CCCGGGCUGGGGAAGCGCGG 20 14544 BCL11A-12339 + CCCCGGGCUGGGGAAGCGCGG 21 14545 BCL11A-12340 + GCCCCGGGCUGGGGAAGCGCGG 22 14546 BCL11A-12341 + AGCCCCGGGCUGGGGAAGCGCGG 23 14547 BCL11A-12342 + CAGCCCCGGGCUGGGGAAGCGCGG 24 14548 BCL11A-12343 + CUGGGGAAGCGCGGGCGG 18 14549 BCL11A-12344 + GCUGGGGAAGCGCGGGCGG 19 14550 BCL11A-10197 + GGCUGGGGAAGCGCGGGCGG 20 14551 BCL11A-12345 + GGGCUGGGGAAGCGCGGGCGG 21 14552 BCL11A-12346 + CGGGCUGGGGAAGCGCGGGCGG 22 14553 BCL11A-12347 + CCGGGCUGGGGAAGCGCGGGCGG 23 14554 BCL11A-12348 + CCCGGGCUGGGGAAGCGCGGGCGG 24 14555 BCL11A-12349 + GCAAAACUGGCGGGGCGG 18 14556 BCL11A-12350 + UGCAAAACUGGCGGGGCGG 19 14557 BCL11A-10198 + UUGCAAAACUGGCGGGGCGG 20 14558 BCL11A-12351 + UUUGCAAAACUGGCGGGGCGG 21 14559 BCL11A-12352 + UUUUGCAAAACUGGCGGGGCGG 22 14560 BCL11A-12353 + AUUUUGCAAAACUGGCGGGGCGG 23 14561 BCL11A-12354 + UAUUUUGCAAAACUGGCGGGGCGG 24 14562 BCL11A-12355 + UGGAAAGAGGGGACCGGG 18 14563 BCL11A-12356 + CUGGAAAGAGGGGACCGGG 19 14564 BCL11A-12357 + CCUGGAAAGAGGGGACCGGG 20 14565 BCL11A-12358 + GCCUGGAAAGAGGGGACCGGG 21 14566 BCL11A-12359 + GGCCUGGAAAGAGGGGACCGGG 22 14567 BCL11A-12360 + CGGCCUGGAAAGAGGGGACCGGG 23 14568 BCL11A-12361 + GCGGCCUGGAAAGAGGGGACCGGG 24 14569 BCL11A-12362 + GGAGGCUGCAGCCCCGGG 18 14570 BCL11A-12363 + GGGAGGCUGCAGCCCCGGG 19 14571 BCL11A-12364 + CGGGAGGCUGCAGCCCCGGG 20 14572 BCL11A-12365 + CCGGGAGGCUGCAGCCCCGGG 21 14573 BCL11A-12366 + ACCGGGAGGCUGCAGCCCCGGG 22 14574 BCL11A-12367 + CACCGGGAGGCUGCAGCCCCGGG 23 14575 BCL11A-12368 + GCACCGGGAGGCUGCAGCCCCGGG 24 14576 BCL11A-12369 + GGGCUGGGGAAGCGCGGG 18 14577 BCL11A-12370 + CGGGCUGGGGAAGCGCGGG 19 14578 BCL11A-10203 + CCGGGCUGGGGAAGCGCGGG 20 14579 BCL11A-12371 + CCCGGGCUGGGGAAGCGCGGG 21 14580 BCL11A-12372 + CCCCGGGCUGGGGAAGCGCGGG 22 14581 BCL11A-12373 + GCCCCGGGCUGGGGAAGCGCGGG 23 14582 BCL11A-12374 + AGCCCCGGGCUGGGGAAGCGCGGG 24 14583 BCL11A-12375 + CAAAACUGGCGGGGCGGG 18 14584 BCL11A-12376 + GCAAAACUGGCGGGGCGGG 19 14585 BCL11A-10204 + UGCAAAACUGGCGGGGCGGG 20 14586 BCL11A-12377 + UUGCAAAACUGGCGGGGCGGG 21 14587 BCL11A-12378 + UUUGCAAAACUGGCGGGGCGGG 22 14588 BCL11A-12379 + UUUUGCAAAACUGGCGGGGCGGG 23 14589 BCL11A-12380 + AUUUUGCAAAACUGGCGGGGCGGG 24 14590 BCL11A-12381 + UUUUGCAAAACUGGCGGG 18 14591 BCL11A-12382 + AUUUUGCAAAACUGGCGGG 19 14592 BCL11A-12383 + UAUUUUGCAAAACUGGCGGG 20 14593 BCL11A-12384 + UUAUUUUGCAAAACUGGCGGG 21 14594 BCL11A-12385 + AUUAUUUUGCAAAACUGGCGGG 22 14595 BCL11A-12386 + CAUUAUUUUGCAAAACUGGCGGG 23 14596 BCL11A-12387 + UCAUUAUUUUGCAAAACUGGCGGG 24 14597 BCL11A-12388 + GCGUGUGGACGCCAGGGG 18 14598 BCL11A-12389 + CGCGUGUGGACGCCAGGGG 19 14599 BCL11A-12390 + CCGCGUGUGGACGCCAGGGG 20 14600 BCL11A-12391 + CCCGCGUGUGGACGCCAGGGG 21 14601 BCL11A-12392 + CCCCGCGUGUGGACGCCAGGGG 22 14602 BCL11A-12393 + UCCCCGCGUGUGGACGCCAGGGG 23 14603 BCL11A-12394 + CUCCCCGCGUGUGGACGCCAGGGG 24 14604 BCL11A-12395 + AAAACUGGCGGGGCGGGG 18 14605 BCL11A-12396 + CAAAACUGGCGGGGCGGGG 19 14606 BCL11A-10207 + GCAAAACUGGCGGGGCGGGG 20 14607 BCL11A-12397 + UGCAAAACUGGCGGGGCGGGG 21 14608 BCL11A-12398 + UUGCAAAACUGGCGGGGCGGGG 22 14609 BCL11A-12399 + UUUGCAAAACUGGCGGGGCGGGG 23 14610 BCL11A-12400 + UUUUGCAAAACUGGCGGGGCGGGG 24 14611 BCL11A-12401 + UUUGCAAAACUGGCGGGG 18 14612 BCL11A-12402 + UUUUGCAAAACUGGCGGGG 19 14613 BCL11A-10208 + AUUUUGCAAAACUGGCGGGG 20 14614 BCL11A-12403 + UAUUUUGCAAAACUGGCGGGG 21 14615 BCL11A-12404 + UUAUUUUGCAAAACUGGCGGGG 22 14616 BCL11A-12405 + AUUAUUUUGCAAAACUGGCGGGG 23 14617 BCL11A-12406 + CAUUAUUUUGCAAAACUGGCGGGG 24 14618 BCL11A-12407 + CGGGCGAGGGGAGGUGGG 18 14619 BCL11A-12408 + GCGGGCGAGGGGAGGUGGG 19 14620 BCL11A-10213 + AGCGGGCGAGGGGAGGUGGG 20 14621 BCL11A-12409 + CAGCGGGCGAGGGGAGGUGGG 21 14622 BCL11A-12410 + GCAGCGGGCGAGGGGAGGUGGG 22 14623 BCL11A-12411 + CGCAGCGGGCGAGGGGAGGUGGG 23 14624 BCL11A-12412 + CCGCAGCGGGCGAGGGGAGGUGGG 24 14625 BCL11A-12413 + AUUAUUUUGCAAAACUGG 18 14626 BCL11A-12414 + CAUUAUUUUGCAAAACUGG 19 14627 BCL11A-10215 + UCAUUAUUUUGCAAAACUGG 20 14628 BCL11A-12415 + UUCAUUAUUUUGCAAAACUGG 21 14629 BCL11A-12416 + GUUCAUUAUUUUGCAAAACUGG 22 14630 BCL11A-12417 + UGUUCAUUAUUUUGCAAAACUGG 23 14631 BCL11A-12418 + UUGUUCAUUAUUUUGCAAAACUGG 24 14632 BCL11A-12419 + ACAAACACCCACCUCUGG 18 14633 BCL11A-12420 + GACAAACACCCACCUCUGG 19 14634 BCL11A-12421 + GGACAAACACCCACCUCUGG 20 14635 BCL11A-12422 + GGGACAAACACCCACCUCUGG 21 14636 BCL11A-12423 + CGGGACAAACACCCACCUCUGG 22 14637 BCL11A-12424 + GCGGGACAAACACCCACCUCUGG 23 14638 BCL11A-12425 + AGCGGGACAAACACCCACCUCUGG 24 14639 BCL11A-12426 + GCGGGCGAGGGGAGGUGG 18 14640 BCL11A-12427 + AGCGGGCGAGGGGAGGUGG 19 14641 BCL11A-12428 + CAGCGGGCGAGGGGAGGUGG 20 14642 BCL11A-12429 + GCAGCGGGCGAGGGGAGGUGG 21 14643 BCL11A-12430 + CGCAGCGGGCGAGGGGAGGUGG 22 14644 BCL11A-12431 + CCGCAGCGGGCGAGGGGAGGUGG 23 14645 BCL11A-12432 + UCCGCAGCGGGCGAGGGGAGGUGG 24 14646 BCL11A-12433 + CAUUAUUUUGCAAAACUG 18 14647 BCL11A-12434 + UCAUUAUUUUGCAAAACUG 19 14648 BCL11A-12435 + UUCAUUAUUUUGCAAAACUG 20 14649 BCL11A-12436 + GUUCAUUAUUUUGCAAAACUG 21 14650 BCL11A-12437 + UGUUCAUUAUUUUGCAAAACUG 22 14651 BCL11A-12438 + UUGUUCAUUAUUUUGCAAAACUG 23 14652 BCL11A-12439 + AUUGUUCAUUAUUUUGCAAAACUG 24 14653 BCL11A-12440 + GGCUGCAGCCCCGGGCUG 18 14654 BCL11A-12441 + AGGCUGCAGCCCCGGGCUG 19 14655 BCL11A-10226 + GAGGCUGCAGCCCCGGGCUG 20 14656 BCL11A-12442 + GGAGGCUGCAGCCCCGGGCUG 21 14657 BCL11A-12443 + GGGAGGCUGCAGCCCCGGGCUG 22 14658 BCL11A-12444 + CGGGAGGCUGCAGCCCCGGGCUG 23 14659 BCL11A-12445 + CCGGGAGGCUGCAGCCCCGGGCUG 24 14660 BCL11A-12446 + GCCACUUUCUCACUAUUG 18 14661 BCL11A-12447 + UGCCACUUUCUCACUAUUG 19 14662 BCL11A-10230 + GUGCCACUUUCUCACUAUUG 20 14663 BCL11A-12448 + AGUGCCACUUUCUCACUAUUG 21 14664 BCL11A-12449 + CAGUGCCACUUUCUCACUAUUG 22 14665 BCL11A-12450 + ACAGUGCCACUUUCUCACUAUUG 23 14666 BCL11A-12451 + CACAGUGCCACUUUCUCACUAUUG 24 14667 BCL11A-12452 + GAAUCCAGCCUAAGUUUG 18 14668 BCL11A-12453 + GGAAUCCAGCCUAAGUUUG 19 14669 BCL11A-12454 + CGGAAUCCAGCCUAAGUUUG 20 14670 BCL11A-12455 + GCGGAAUCCAGCCUAAGUUUG 21 14671 BCL11A-12456 + CGCGGAAUCCAGCCUAAGUUUG 22 14672 BCL11A-12457 + ACGCGGAAUCCAGCCUAAGUUUG 23 14673 BCL11A-12458 + AACGCGGAAUCCAGCCUAAGUUUG 24 14674 BCL11A-12459 + CUCCCGACUCCGCGGACU 18 14675 BCL11A-12460 + UCUCCCGACUCCGCGGACU 19 14676 BCL11A-12461 + CUCUCCCGACUCCGCGGACU 20 14677 BCL11A-12462 + CCUCUCCCGACUCCGCGGACU 21 14678 BCL11A-12463 + CCCUCUCCCGACUCCGCGGACU 22 14679 BCL11A-12464 + CCCCUCUCCCGACUCCGCGGACU 23 14680 BCL11A-12465 + GCCCCUCUCCCGACUCCGCGGACU 24 14681 BCL11A-12466 + CGAGCCCGCGGCUGCGCU 18 14682 BCL11A-12467 + CCGAGCCCGCGGCUGCGCU 19 14683 BCL11A-10239 + CCCGAGCCCGCGGCUGCGCU 20 14684 BCL11A-12468 + CCCCGAGCCCGCGGCUGCGCU 21 14685 BCL11A-12469 + GCCCCGAGCCCGCGGCUGCGCU 22 14686 BCL11A-12470 + AGCCCCGAGCCCGCGGCUGCGCU 23 14687 BCL11A-12471 + AAGCCCCGAGCCCGCGGCUGCGCU 24 14688 BCL11A-12472 + AGGCUGCAGCCCCGGGCU 18 14689 BCL11A-12473 + GAGGCUGCAGCCCCGGGCU 19 14690 BCL11A-10240 + GGAGGCUGCAGCCCCGGGCU 20 14691 BCL11A-12474 + GGGAGGCUGCAGCCCCGGGCU 21 14692 BCL11A-12475 + CGGGAGGCUGCAGCCCCGGGCU 22 14693 BCL11A-12476 + CCGGGAGGCUGCAGCCCCGGGCU 23 14694 BCL11A-12477 + ACCGGGAGGCUGCAGCCCCGGGCU 24 14695 BCL11A-12478 + GCGGAAUCCAGCCUAAGU 18 14696 BCL11A-12479 + CGCGGAAUCCAGCCUAAGU 19 14697 BCL11A-12480 + ACGCGGAAUCCAGCCUAAGU 20 14698 BCL11A-12481 + AACGCGGAAUCCAGCCUAAGU 21 14699 BCL11A-12482 + CAACGCGGAAUCCAGCCUAAGU 22 14700 BCL11A-12483 + GCAACGCGGAAUCCAGCCUAAGU 23 14701 BCL11A-12484 + GGCAACGCGGAAUCCAGCCUAAGU 24 14702 BCL11A-12485 + CAUUUUCUUACGGUGAGU 18 14703 BCL11A-12486 + CCAUUUUCUUACGGUGAGU 19 14704 BCL11A-10244 + CCCAUUUUCUUACGGUGAGU 20 14705 BCL11A-12487 + CCCCAUUUUCUUACGGUGAGU 21 14706 BCL11A-12488 + CCCCCAUUUUCUUACGGUGAGU 22 14707 BCL11A-12489 + CCCCCCAUUUUCUUACGGUGAGU 23 14708 BCL11A-12490 + CCCCCCCAUUUUCUUACGGUGAGU 24 14709 BCL11A-12491 + CGCGCUCGCUCCCCGCGU 18 14710 BCL11A-12492 + CCGCGCUCGCUCCCCGCGU 19 14711 BCL11A-12493 + GCCGCGCUCGCUCCCCGCGU 20 14712 BCL11A-12494 + CGCCGCGCUCGCUCCCCGCGU 21 14713 BCL11A-12495 + CCGCCGCGCUCGCUCCCCGCGU 22 14714 BCL11A-12496 + GCCGCCGCGCUCGCUCCCCGCGU 23 14715 BCL11A-12497 + CGCCGCCGCGCUCGCUCCCCGCGU 24 14716 BCL11A-12498 + CAGCGGGCGAGGGGAGGU 18 14717 BCL11A-12499 + GCAGCGGGCGAGGGGAGGU 19 14718 BCL11A-10247 + CGCAGCGGGCGAGGGGAGGU 20 14719 BCL11A-12500 + CCGCAGCGGGCGAGGGGAGGU 21 14720 BCL11A-12501 + UCCGCAGCGGGCGAGGGGAGGU 22 14721 BCL11A-12502 + CUCCGCAGCGGGCGAGGGGAGGU 23 14722 BCL11A-12503 + GCUCCGCAGCGGGCGAGGGGAGGU 24 14723 BCL11A-12504 + GUUUGGAGGGCUGCGGGU 18 14724 BCL11A-12505 + AGUUUGGAGGGCUGCGGGU 19 14725 BCL11A-12506 + AAGUUUGGAGGGCUGCGGGU 20 14726 BCL11A-12507 + UAAGUUUGGAGGGCUGCGGGU 21 14727 BCL11A-12508 + CUAAGUUUGGAGGGCUGCGGGU 22 14728 BCL11A-12509 + CCUAAGUUUGGAGGGCUGCGGGU 23 14729 BCL11A-12510 + GCCUAAGUUUGGAGGGCUGCGGGU 24 14730 BCL11A-12511 + UGCCACUUUCUCACUAUU 18 14731 BCL11A-12512 + GUGCCACUUUCUCACUAUU 19 14732 BCL11A-12513 + AGUGCCACUUUCUCACUAUU 20 14733 BCL11A-12514 + CAGUGCCACUUUCUCACUAUU 21 14734 BCL11A-12515 + ACAGUGCCACUUUCUCACUAUU 22 14735 BCL11A-12516 + CACAGUGCCACUUUCUCACUAUU 23 14736 BCL11A-12517 + CCACAGUGCCACUUUCUCACUAUU 24 14737 BCL11A-12518 + GAAAAAUCACCCGAAGUU 18 14738 BCL11A-12519 + AGAAAAAUCACCCGAAGUU 19 14739 BCL11A-12520 + AAGAAAAAUCACCCGAAGUU 20 14740 BCL11A-12521 + AAAGAAAAAUCACCCGAAGUU 21 14741 BCL11A-12522 + CAAAGAAAAAUCACCCGAAGUU 22 14742 BCL11A-12523 + GCAAAGAAAAAUCACCCGAAGUU 23 14743 BCL11A-12524 + AGCAAAGAAAAAUCACCCGAAGUU 24 14744 BCL11A-12525 + CGGAAUCCAGCCUAAGUU 18 14745 BCL11A-12526 + GCGGAAUCCAGCCUAAGUU 19 14746 BCL11A-10257 + CGCGGAAUCCAGCCUAAGUU 20 14747 BCL11A-12527 + ACGCGGAAUCCAGCCUAAGUU 21 14748 BCL11A-12528 + AACGCGGAAUCCAGCCUAAGUU 22 14749 BCL11A-12529 + CAACGCGGAAUCCAGCCUAAGUU 23 14750 BCL11A-12530 + GCAACGCGGAAUCCAGCCUAAGUU 24 14751 BCL11A-12531 + GAAUCAUUGCAUUCCUUU 18 14752 BCL11A-12532 + GGAAUCAUUGCAUUCCUUU 19 14753 BCL11A-12533 + UGGAAUCAUUGCAUUCCUUU 20 14754 BCL11A-12534 + GUGGAAUCAUUGCAUUCCUUU 21 14755 BCL11A-12535 + AGUGGAAUCAUUGCAUUCCUUU 22 14756 BCL11A-12536 + GAGUGGAAUCAUUGCAUUCCUUU 23 14757 BCL11A-12537 + GGAGUGGAAUCAUUGCAUUCCUUU 24 14758 BCL11A-12538 - CCACUCACCGUAAGAAAA 18 14759 BCL11A-12539 - CCCACUCACCGUAAGAAAA 19 14760 BCL11A-10024 - UCCCACUCACCGUAAGAAAA 20 14761 BCL11A-12540 - UUCCCACUCACCGUAAGAAAA 21 14762 BCL11A-12541 - CUUCCCACUCACCGUAAGAAAA 22 14763 BCL11A-12542 - GCUUCCCACUCACCGUAAGAAAA 23 14764 BCL11A-12543 - UGCUUCCCACUCACCGUAAGAAAA 24 14765 BCL11A-12544 - CCCACUCACCGUAAGAAA 18 14766 BCL11A-12545 - UCCCACUCACCGUAAGAAA 19 14767 BCL11A-12546 - UUCCCACUCACCGUAAGAAA 20 14768 BCL11A-12547 - CUUCCCACUCACCGUAAGAAA 21 14769 BCL11A-12548 - GCUUCCCACUCACCGUAAGAAA 22 14770 BCL11A-12549 - UGCUUCCCACUCACCGUAAGAAA 23 14771 BCL11A-12550 - UUGCUUCCCACUCACCGUAAGAAA 24 14772 BCL11A-12551 - UGGGAGCUGGUGGGGAAA 18 14773 BCL11A-12552 - GUGGGAGCUGGUGGGGAAA 19 14774 BCL11A-10028 - GGUGGGAGCUGGUGGGGAAA 20 14775 BCL11A-12553 - GGGUGGGAGCUGGUGGGGAAA 21 14776 BCL11A-12554 - GGGGUGGGAGCUGGUGGGGAAA 22 14777 BCL11A-12555 - GGGGGUGGGAGCUGGUGGGGAAA 23 14778 BCL11A-12556 - UGGGGGUGGGAGCUGGUGGGGAAA 24 14779 BCL11A-12557 - AACGAUUCCCGGGGAGAA 18 14780 BCL11A-12558 - AAACGAUUCCCGGGGAGAA 19 14781 BCL11A-12559 - AAAACGAUUCCCGGGGAGAA 20 14782 BCL11A-12560 - AAAAACGAUUCCCGGGGAGAA 21 14783 BCL11A-12561 - AAAAAACGAUUCCCGGGGAGAA 22 14784 BCL11A-12562 - UAAAAAACGAUUCCCGGGGAGAA 23 14785 BCL11A-12563 - CUAAAAAACGAUUCCCGGGGAGAA 24 14786 BCL11A-12564 - UUUAUUUCUCUUUUCGAA 18 14787 BCL11A-12565 - CUUUAUUUCUCUUUUCGAA 19 14788 BCL11A-12566 - GCUUUAUUUCUCUUUUCGAA 20 14789 BCL11A-12567 - CGCUUUAUUUCUCUUUUCGAA 21 14790 BCL11A-12568 - CCGCUUUAUUUCUCUUUUCGAA 22 14791 BCL11A-12569 - GCCGCUUUAUUUCUCUUUUCGAA 23 14792 BCL11A-12570 - CGCCGCUUUAUUUCUCUUUUCGAA 24 14793 BCL11A-12571 - GUGGGAGCUGGUGGGGAA 18 14794 BCL11A-12572 - GGUGGGAGCUGGUGGGGAA 19 14795 BCL11A-10032 - GGGUGGGAGCUGGUGGGGAA 20 14796 BCL11A-12573 - GGGGUGGGAGCUGGUGGGGAA 21 14797 BCL11A-12574 - GGGGGUGGGAGCUGGUGGGGAA 22 14798 BCL11A-12575 - UGGGGGUGGGAGCUGGUGGGGAA 23 14799 BCL11A-12576 - CUGGGGGUGGGAGCUGGUGGGGAA 24 14800 BCL11A-12577 - GAAAGUGGCACUGUGGAA 18 14801 BCL11A-12578 - AGAAAGUGGCACUGUGGAA 19 14802 BCL11A-10033 - GAGAAAGUGGCACUGUGGAA 20 14803 BCL11A-12579 - UGAGAAAGUGGCACUGUGGAA 21 14804 BCL11A-12580 - GUGAGAAAGUGGCACUGUGGAA 22 14805 BCL11A-12581 - AGUGAGAAAGUGGCACUGUGGAA 23 14806 BCL11A-12582 - UAGUGAGAAAGUGGCACUGUGGAA 24 14807 BCL11A-12583 - CUCACGGUCAAGUGUGCA 18 14808 BCL11A-12584 - GCUCACGGUCAAGUGUGCA 19 14809 BCL11A-12585 - CGCUCACGGUCAAGUGUGCA 20 14810 BCL11A-12586 - GCGCUCACGGUCAAGUGUGCA 21 14811 BCL11A-12587 - CGCGCUCACGGUCAAGUGUGCA 22 14812 BCL11A-12588 - GCGCGCUCACGGUCAAGUGUGCA 23 14813 BCL11A-12589 - AGCGCGCUCACGGUCAAGUGUGCA 24 14814 BCL11A-12590 - GGAGAGGGGCCGCGGCGA 18 14815 BCL11A-12591 - GGGAGAGGGGCCGCGGCGA 19 14816 BCL11A-10043 - CGGGAGAGGGGCCGCGGCGA 20 14817 BCL11A-12592 - UCGGGAGAGGGGCCGCGGCGA 21 14818 BCL11A-12593 - GUCGGGAGAGGGGCCGCGGCGA 22 14819 BCL11A-12594 - AGUCGGGAGAGGGGCCGCGGCGA 23 14820 BCL11A-12595 - GAGUCGGGAGAGGGGCCGCGGCGA 24 14821 BCL11A-12596 - CCGUGGGACCGGGAAGGA 18 14822 BCL11A-12597 - GCCGUGGGACCGGGAAGGA 19 14823 BCL11A-10045 - AGCCGUGGGACCGGGAAGGA 20 14824 BCL11A-12598 - GAGCCGUGGGACCGGGAAGGA 21 14825 BCL11A-12599 - AGAGCCGUGGGACCGGGAAGGA 22 14826 BCL11A-12600 - GAGAGCCGUGGGACCGGGAAGGA 23 14827 BCL11A-12601 - GGAGAGCCGUGGGACCGGGAAGGA 24 14828 BCL11A-12602 - GAGUCCGCGGAGUCGGGA 18 14829 BCL11A-12603 - UGAGUCCGCGGAGUCGGGA 19 14830 BCL11A-12604 - CUGAGUCCGCGGAGUCGGGA 20 14831 BCL11A-12605 - CCUGAGUCCGCGGAGUCGGGA 21 14832 BCL11A-12606 - UCCUGAGUCCGCGGAGUCGGGA 22 14833 BCL11A-12607 - CUCCUGAGUCCGCGGAGUCGGGA 23 14834 BCL11A-12608 - GCUCCUGAGUCCGCGGAGUCGGGA 24 14835 BCL11A-12609 - GGCGUCCACACGCGGGGA 18 14836 BCL11A-12610 - UGGCGUCCACACGCGGGGA 19 14837 BCL11A-12611 - CUGGCGUCCACACGCGGGGA 20 14838 BCL11A-12612 - CCUGGCGUCCACACGCGGGGA 21 14839 BCL11A-12613 - CCCUGGCGUCCACACGCGGGGA 22 14840 BCL11A-12614 - CCCCUGGCGUCCACACGCGGGGA 23 14841 BCL11A-12615 - GCCCCUGGCGUCCACACGCGGGGA 24 14842 BCL11A-12616 - GCGCGGCGGCGGCGGGGA 18 14843 BCL11A-12617 - AGCGCGGCGGCGGCGGGGA 19 14844 BCL11A-10051 - GAGCGCGGCGGCGGCGGGGA 20 14845 BCL11A-12618 - CGAGCGCGGCGGCGGCGGGGA 21 14846 BCL11A-12619 - GCGAGCGCGGCGGCGGCGGGGA 22 14847 BCL11A-12620 - AGCGAGCGCGGCGGCGGCGGGGA 23 14848 BCL11A-12621 - GAGCGAGCGCGGCGGCGGCGGGGA 24 14849 BCL11A-12622 - GGUGGGAGCUGGUGGGGA 18 14850 BCL11A-12623 - GGGUGGGAGCUGGUGGGGA 19 14851 BCL11A-12624 - GGGGUGGGAGCUGGUGGGGA 20 14852 BCL11A-12625 - GGGGGUGGGAGCUGGUGGGGA 21 14853 BCL11A-12626 - UGGGGGUGGGAGCUGGUGGGGA 22 14854 BCL11A-12627 - CUGGGGGUGGGAGCUGGUGGGGA 23 14855 BCL11A-12628 - CCUGGGGGUGGGAGCUGGUGGGGA 24 14856 BCL11A-12629 - ACGGGGAGAGCCGUGGGA 18 14857 BCL11A-12630 - GACGGGGAGAGCCGUGGGA 19 14858 BCL11A-12631 - CGACGGGGAGAGCCGUGGGA 20 14859 BCL11A-12632 - GCGACGGGGAGAGCCGUGGGA 21 14860 BCL11A-12633 - GGCGACGGGGAGAGCCGUGGGA 22 14861 BCL11A-12634 - CGGCGACGGGGAGAGCCGUGGGA 23 14862 BCL11A-12635 - GCGGCGACGGGGAGAGCCGUGGGA 24 14863 BCL11A-12636 - AGAAAGUGGCACUGUGGA 18 14864 BCL11A-12637 - GAGAAAGUGGCACUGUGGA 19 14865 BCL11A-12638 - UGAGAAAGUGGCACUGUGGA 20 14866 BCL11A-12639 - GUGAGAAAGUGGCACUGUGGA 21 14867 BCL11A-12640 - AGUGAGAAAGUGGCACUGUGGA 22 14868 BCL11A-12641 - UAGUGAGAAAGUGGCACUGUGGA 23 14869 BCL11A-12642 - AUAGUGAGAAAGUGGCACUGUGGA 24 14870 BCL11A-12643 - CGCCAGUUUUGCAAAAUA 18 14871 BCL11A-12644 - CCGCCAGUUUUGCAAAAUA 19 14872 BCL11A-12645 - CCCGCCAGUUUUGCAAAAUA 20 14873 BCL11A-12646 - CCCCGCCAGUUUUGCAAAAUA 21 14874 BCL11A-12647 - GCCCCGCCAGUUUUGCAAAAUA 22 14875 BCL11A-12648 - CGCCCCGCCAGUUUUGCAAAAUA 23 14876 BCL11A-12649 - CCGCCCCGCCAGUUUUGCAAAAUA 24 14877 BCL11A-12650 - GUAGUCAUCCCCACAAUA 18 14878 BCL11A-12651 - AGUAGUCAUCCCCACAAUA 19 14879 BCL11A-12652 - AAGUAGUCAUCCCCACAAUA 20 14880 BCL11A-12653 - AAAGUAGUCAUCCCCACAAUA 21 14881 BCL11A-12654 - GAAAGUAGUCAUCCCCACAAUA 22 14882 BCL11A-12655 - GGAAAGUAGUCAUCCCCACAAUA 23 14883 BCL11A-12656 - AGGAAAGUAGUCAUCCCCACAAUA 24 14884 BCL11A-12657 - GGGAAGUGGGUGUGCGUA 18 14885 BCL11A-12658 - GGGGAAGUGGGUGUGCGUA 19 14886 BCL11A-10055 - AGGGGAAGUGGGUGUGCGUA 20 14887 BCL11A-12659 - GAGGGGAAGUGGGUGUGCGUA 21 14888 BCL11A-12660 - GGAGGGGAAGUGGGUGUGCGUA 22 14889 BCL11A-12661 - GGGAGGGGAAGUGGGUGUGCGUA 23 14890 BCL11A-12662 - GGGGAGGGGAAGUGGGUGUGCGUA 24 14891 BCL11A-12663 - UAAGAAAAUGGGGGGGUA 18 14892 BCL11A-12664 - GUAAGAAAAUGGGGGGGUA 19 14893 BCL11A-10056 - CGUAAGAAAAUGGGGGGGUA 20 14894 BCL11A-12665 - CCGUAAGAAAAUGGGGGGGUA 21 14895 BCL11A-12666 - ACCGUAAGAAAAUGGGGGGGUA 22 14896 BCL11A-12667 - CACCGUAAGAAAAUGGGGGGGUA 23 14897 BCL11A-12668 - UCACCGUAAGAAAAUGGGGGGGUA 24 14898 BCL11A-12669 - AACAACUCACAUGCAAAC 18 14899 BCL11A-12670 - GAACAACUCACAUGCAAAC 19 14900 BCL11A-12671 - CGAACAACUCACAUGCAAAC 20 14901 BCL11A-12672 - GCGAACAACUCACAUGCAAAC 21 14902 BCL11A-12673 - UGCGAACAACUCACAUGCAAAC 22 14903 BCL11A-12674 - UUGCGAACAACUCACAUGCAAAC 23 14904 BCL11A-12675 - GUUGCGAACAACUCACAUGCAAAC 24 14905 BCL11A-12676 - CCGCUGCGGAGCUGUAAC 18 14906 BCL11A-12677 - CCCGCUGCGGAGCUGUAAC 19 14907 BCL11A-12678 - GCCCGCUGCGGAGCUGUAAC 20 14908 BCL11A-12679 - CGCCCGCUGCGGAGCUGUAAC 21 14909 BCL11A-12680 - UCGCCCGCUGCGGAGCUGUAAC 22 14910 BCL11A-12681 - CUCGCCCGCUGCGGAGCUGUAAC 23 14911 BCL11A-12682 - CCUCGCCCGCUGCGGAGCUGUAAC 24 14912 BCL11A-12683 - GGCCCCUGGCGUCCACAC 18 14913 BCL11A-12684 - CGGCCCCUGGCGUCCACAC 19 14914 BCL11A-12685 - UCGGCCCCUGGCGUCCACAC 20 14915 BCL11A-12686 - UUCGGCCCCUGGCGUCCACAC 21 14916 BCL11A-12687 - CUUCGGCCCCUGGCGUCCACAC 22 14917 BCL11A-12688 - ACUUCGGCCCCUGGCGUCCACAC 23 14918 BCL11A-12689 - UACUUCGGCCCCUGGCGUCCACAC 24 14919 BCL11A-12690 - GCGCGGGCUCCUGGAGAC 18 14920 BCL11A-12691 - CGCGCGGGCUCCUGGAGAC 19 14921 BCL11A-12692 - CCGCGCGGGCUCCUGGAGAC 20 14922 BCL11A-12693 - GCCGCGCGGGCUCCUGGAGAC 21 14923 BCL11A-12694 - GGCCGCGCGGGCUCCUGGAGAC 22 14924 BCL11A-12695 - AGGCCGCGCGGGCUCCUGGAGAC 23 14925 BCL11A-12696 - CAGGCCGCGCGGGCUCCUGGAGAC 24 14926 BCL11A-12697 - GAGAGGGGCCGCGGCGAC 18 14927 BCL11A-12698 - GGAGAGGGGCCGCGGCGAC 19 14928 BCL11A-10061 - GGGAGAGGGGCCGCGGCGAC 20 14929 BCL11A-12699 - CGGGAGAGGGGCCGCGGCGAC 21 14930 BCL11A-12700 - UCGGGAGAGGGGCCGCGGCGAC 22 14931 BCL11A-12701 - GUCGGGAGAGGGGCCGCGGCGAC 23 14932 BCL11A-12702 - AGUCGGGAGAGGGGCCGCGGCGAC 24 14933 BCL11A-12703 - CGUGGGACCGGGAAGGAC 18 14934 BCL11A-12704 - CCGUGGGACCGGGAAGGAC 19 14935 BCL11A-10062 - GCCGUGGGACCGGGAAGGAC 20 14936 BCL11A-12705 - AGCCGUGGGACCGGGAAGGAC 21 14937 BCL11A-12706 - GAGCCGUGGGACCGGGAAGGAC 22 14938 BCL11A-12707 - AGAGCCGUGGGACCGGGAAGGAC 23 14939 BCL11A-12708 - GAGAGCCGUGGGACCGGGAAGGAC 24 14940 BCL11A-12709 - CGGGGAGAGCCGUGGGAC 18 14941 BCL11A-12710 - ACGGGGAGAGCCGUGGGAC 19 14942 BCL11A-10065 - GACGGGGAGAGCCGUGGGAC 20 14943 BCL11A-12711 - CGACGGGGAGAGCCGUGGGAC 21 14944 BCL11A-12712 - GCGACGGGGAGAGCCGUGGGAC 22 14945 BCL11A-12713 - GGCGACGGGGAGAGCCGUGGGAC 23 14946 BCL11A-12714 - CGGCGACGGGGAGAGCCGUGGGAC 24 14947 BCL11A-12715 - ACAACUCACAUGCAAACC 18 14948 BCL11A-12716 - AACAACUCACAUGCAAACC 19 14949 BCL11A-10066 - GAACAACUCACAUGCAAACC 20 14950 BCL11A-12717 - CGAACAACUCACAUGCAAACC 21 14951 BCL11A-12718 - GCGAACAACUCACAUGCAAACC 22 14952 BCL11A-12719 - UGCGAACAACUCACAUGCAAACC 23 14953 BCL11A-12720 - UUGCGAACAACUCACAUGCAAACC 24 14954 BCL11A-12721 - GGGGAGAGCCGUGGGACC 18 14955 BCL11A-12722 - CGGGGAGAGCCGUGGGACC 19 14956 BCL11A-10070 - ACGGGGAGAGCCGUGGGACC 20 14957 BCL11A-12723 - GACGGGGAGAGCCGUGGGACC 21 14958 BCL11A-12724 - CGACGGGGAGAGCCGUGGGACC 22 14959 BCL11A-12725 - GCGACGGGGAGAGCCGUGGGACC 23 14960 BCL11A-12726 - GGCGACGGGGAGAGCCGUGGGACC 24 14961 BCL11A-12727 - UCGGCCUUGGGGGCGCCC 18 14962 BCL11A-12728 - CUCGGCCUUGGGGGCGCCC 19 14963 BCL11A-12729 - GCUCGGCCUUGGGGGCGCCC 20 14964 BCL11A-12730 - GGCUCGGCCUUGGGGGCGCCC 21 14965 BCL11A-12731 - UGGCUCGGCCUUGGGGGCGCCC 22 14966 BCL11A-12732 - CUGGCUCGGCCUUGGGGGCGCCC 23 14967 BCL11A-12733 - CCUGGCUCGGCCUUGGGGGCGCCC 24 14968 BCL11A-12734 - GUCUAAAAAACGAUUCCC 18 14969 BCL11A-12735 - AGUCUAAAAAACGAUUCCC 19 14970 BCL11A-10082 - AAGUCUAAAAAACGAUUCCC 20 14971 BCL11A-12736 - CAAGUCUAAAAAACGAUUCCC 21 14972 BCL11A-12737 - ACAAGUCUAAAAAACGAUUCCC 22 14973 BCL11A-12738 - UACAAGUCUAAAAAACGAUUCCC 23 14974 BCL11A-12739 - GUACAAGUCUAAAAAACGAUUCCC 24 14975 BCL11A-12740 - GCCCGCGCUUCCCCAGCC 18 14976 BCL11A-12741 - CGCCCGCGCUUCCCCAGCC 19 14977 BCL11A-10084 - CCGCCCGCGCUUCCCCAGCC 20 14978 BCL11A-12742 - UCCGCCCGCGCUUCCCCAGCC 21 14979 BCL11A-12743 - CUCCGCCCGCGCUUCCCCAGCC 22 14980 BCL11A-12744 - CCUCCGCCCGCGCUUCCCCAGCC 23 14981 BCL11A-12745 - CCCUCCGCCCGCGCUUCCCCAGCC 24 14982 BCL11A-12746 - AGUUUCCCGAGCGCAGCC 18 14983 BCL11A-12747 - AAGUUUCCCGAGCGCAGCC 19 14984 BCL11A-12748 - AAAGUUUCCCGAGCGCAGCC 20 14985 BCL11A-12749 - CAAAGUUUCCCGAGCGCAGCC 21 14986 BCL11A-12750 - GCAAAGUUUCCCGAGCGCAGCC 22 14987 BCL11A-12751 - GGCAAAGUUUCCCGAGCGCAGCC 23 14988 BCL11A-12752 - GGGCAAAGUUUCCCGAGCGCAGCC 24 14989 BCL11A-12753 - GCGGCGACGGGGAGAGCC 18 14990 BCL11A-12754 - CGCGGCGACGGGGAGAGCC 19 14991 BCL11A-12755 - CCGCGGCGACGGGGAGAGCC 20 14992 BCL11A-12756 - GCCGCGGCGACGGGGAGAGCC 21 14993 BCL11A-12757 - GGCCGCGGCGACGGGGAGAGCC 22 14994 BCL11A-12758 - GGGCCGCGGCGACGGGGAGAGCC 23 14995 BCL11A-12759 - GGGGCCGCGGCGACGGGGAGAGCC 24 14996 BCL11A-12760 - CCGGUCCCUGGCUCGGCC 18 14997 BCL11A-12761 - CCCGGUCCCUGGCUCGGCC 19 14998 BCL11A-12762 - UCCCGGUCCCUGGCUCGGCC 20 14999 BCL11A-12763 - CCAGGCCGCGCGGGCUCC 18 15000 BCL11A-12764 - UCCAGGCCGCGCGGGCUCC 19 15001 BCL11A-10091 - UUCCAGGCCGCGCGGGCUCC 20 15002 BCL11A-12765 - UUUCCAGGCCGCGCGGGCUCC 21 15003 BCL11A-12766 - CUUUCCAGGCCGCGCGGGCUCC 22 15004 BCL11A-12767 - UCUUUCCAGGCCGCGCGGGCUCC 23 15005 BCL11A-12768 - CUCUUUCCAGGCCGCGCGGGCUCC 24 15006 BCL11A-12769 - UUCUUUGCUGUCCUCUCC 18 15007 BCL11A-12770 - UUUCUUUGCUGUCCUCUCC 19 15008 BCL11A-12771 - UUUUCUUUGCUGUCCUCUCC 20 15009 BCL11A-12772 - UUUUUCUUUGCUGUCCUCUCC 21 15010 BCL11A-12773 - AUUUUUCUUUGCUGUCCUCUCC 22 15011 BCL11A-12774 - GAUUUUUCUUUGCUGUCCUCUCC 23 15012 BCL11A-12775 - UGAUUUUUCUUUGCUGUCCUCUCC 24 15013 BCL11A-12776 - CCCGGCGCUCCUGAGUCC 18 15014 BCL11A-12777 - CCCCGGCGCUCCUGAGUCC 19 15015 BCL11A-12778 - CCCCCGGCGCUCCUGAGUCC 20 15016 BCL11A-12779 - GCCCCCGGCGCUCCUGAGUCC 21 15017 BCL11A-12780 - GGCCCCCGGCGCUCCUGAGUCC 22 15018 BCL11A-12781 - GGGCCCCCGGCGCUCCUGAGUCC 23 15019 BCL11A-12782 - GGGGCCCCCGGCGCUCCUGAGUCC 24 15020 BCL11A-12783 - GUACGGAGGAGGGUGUCC 18 15021 BCL11A-12784 - CGUACGGAGGAGGGUGUCC 19 15022 BCL11A-10094 - GCGUACGGAGGAGGGUGUCC 20 15023 BCL11A-12785 - UGCGUACGGAGGAGGGUGUCC 21 15024 BCL11A-12786 - GUGCGUACGGAGGAGGGUGUCC 22 15025 BCL11A-12787 - UGUGCGUACGGAGGAGGGUGUCC 23 15026 BCL11A-12788 - GUGUGCGUACGGAGGAGGGUGUCC 24 15027 BCL11A-12789 - AGUCUAAAAAACGAUUCC 18 15028 BCL11A-12790 - AAGUCUAAAAAACGAUUCC 19 15029 BCL11A-10095 - CAAGUCUAAAAAACGAUUCC 20 15030 BCL11A-12791 - ACAAGUCUAAAAAACGAUUCC 21 15031 BCL11A-12792 - UACAAGUCUAAAAAACGAUUCC 22 15032 BCL11A-12793 - GUACAAGUCUAAAAAACGAUUCC 23 15033 BCL11A-12794 - AGUACAAGUCUAAAAAACGAUUCC 24 15034 BCL11A-12795 - CGCCCGCGCUUCCCCAGC 18 15035 BCL11A-12796 - CCGCCCGCGCUUCCCCAGC 19 15036 BCL11A-12797 - UCCGCCCGCGCUUCCCCAGC 20 15037 BCL11A-12798 - CUCCGCCCGCGCUUCCCCAGC 21 15038 BCL11A-12799 - CCUCCGCCCGCGCUUCCCCAGC 22 15039 BCL11A-12800 - CCCUCCGCCCGCGCUUCCCCAGC 23 15040 BCL11A-12801 - UCCCUCCGCCCGCGCUUCCCCAGC 24 15041 BCL11A-12802 - CACGGUCAAGUGUGCAGC 18 15042 BCL11A-12803 - UCACGGUCAAGUGUGCAGC 19 15043 BCL11A-10100 - CUCACGGUCAAGUGUGCAGC 20 15044 BCL11A-12804 - GCUCACGGUCAAGUGUGCAGC 21 15045 BCL11A-12805 - CGCUCACGGUCAAGUGUGCAGC 22 15046 BCL11A-12806 - GCGCUCACGGUCAAGUGUGCAGC 23 15047 BCL11A-12807 - CGCGCUCACGGUCAAGUGUGCAGC 24 15048 BCL11A-12808 - CCCCUGGCGUCCACACGC 18 15049 BCL11A-12809 - GCCCCUGGCGUCCACACGC 19 15050 BCL11A-10103 - GGCCCCUGGCGUCCACACGC 20 15051 BCL11A-12810 - CGGCCCCUGGCGUCCACACGC 21 15052 BCL11A-12811 - UCGGCCCCUGGCGUCCACACGC 22 15053 BCL11A-12812 - UUCGGCCCCUGGCGUCCACACGC 23 15054 BCL11A-12813 - CUUCGGCCCCUGGCGUCCACACGC 24 15055 BCL11A-12814 - CCCCUCUUUCCAGGCCGC 18 15056 BCL11A-12815 - UCCCCUCUUUCCAGGCCGC 19 15057 BCL11A-12816 - GUCCCCUCUUUCCAGGCCGC 20 15058 BCL11A-12817 - GGUCCCCUCUUUCCAGGCCGC 21 15059 BCL11A-12818 - CGGUCCCCUCUUUCCAGGCCGC 22 15060 BCL11A-12819 - CCGGUCCCCUCUUUCCAGGCCGC 23 15061 BCL11A-12820 - CCCGGUCCCCUCUUUCCAGGCCGC 24 15062 BCL11A-12821 - GCCGCCUUUUGUUCCGGC 18 15063 BCL11A-12822 - UGCCGCCUUUUGUUCCGGC 19 15064 BCL11A-12823 - CUGCCGCCUUUUGUUCCGGC 20 15065 BCL11A-12824 - ACUGCCGCCUUUUGUUCCGGC 21 15066 BCL11A-12825 - CACUGCCGCCUUUUGUUCCGGC 22 15067 BCL11A-12826 - GCACUGCCGCCUUUUGUUCCGGC 23 15068 BCL11A-12827 - GGCACUGCCGCCUUUUGUUCCGGC 24 15069 BCL11A-12828 - AGCGAGCGCGGCGGCGGC 18 15070 BCL11A-12829 - GAGCGAGCGCGGCGGCGGC 19 15071 BCL11A-10114 - GGAGCGAGCGCGGCGGCGGC 20 15072 BCL11A-12830 - GGGAGCGAGCGCGGCGGCGGC 21 15073 BCL11A-12831 - GGGGAGCGAGCGCGGCGGCGGC 22 15074 BCL11A-12832 - CGGGGAGCGAGCGCGGCGGCGGC 23 15075 BCL11A-12833 - GCGGGGAGCGAGCGCGGCGGCGGC 24 15076 BCL11A-12834 - CCGAGCGCAGCCGCGGGC 18 15077 BCL11A-12835 - CCCGAGCGCAGCCGCGGGC 19 15078 BCL11A-12836 - UCCCGAGCGCAGCCGCGGGC 20 15079 BCL11A-12837 - UUCCCGAGCGCAGCCGCGGGC 21 15080 BCL11A-12838 - UUUCCCGAGCGCAGCCGCGGGC 22 15081 BCL11A-12839 - GUUUCCCGAGCGCAGCCGCGGGC 23 15082 BCL11A-12840 - AGUUUCCCGAGCGCAGCCGCGGGC 24 15083 BCL11A-12841 - UCCAGGCCGCGCGGGCUC 18 15084 BCL11A-12842 - UUCCAGGCCGCGCGGGCUC 19 15085 BCL11A-12843 - UUUCCAGGCCGCGCGGGCUC 20 15086 BCL11A-12844 - CUUUCCAGGCCGCGCGGGCUC 21 15087 BCL11A-12845 - UCUUUCCAGGCCGCGCGGGCUC 22 15088 BCL11A-12846 - CUCUUUCCAGGCCGCGCGGGCUC 23 15089 BCL11A-12847 - CCUCUUUCCAGGCCGCGCGGGCUC 24 15090 BCL11A-12848 - UCCUGAGUCCGCGGAGUC 18 15091 BCL11A-12849 - CUCCUGAGUCCGCGGAGUC 19 15092 BCL11A-10128 - GCUCCUGAGUCCGCGGAGUC 20 15093 BCL11A-12850 - CGCUCCUGAGUCCGCGGAGUC 21 15094 BCL11A-12851 - GCGCUCCUGAGUCCGCGGAGUC 22 15095 BCL11A-12852 - GGCGCUCCUGAGUCCGCGGAGUC 23 15096 BCL11A-12853 - CGGCGCUCCUGAGUCCGCGGAGUC 24 15097 BCL11A-12854 - CGUACGGAGGAGGGUGUC 18 15098 BCL11A-12855 - GCGUACGGAGGAGGGUGUC 19 15099 BCL11A-10130 - UGCGUACGGAGGAGGGUGUC 20 15100 BCL11A-12856 - GUGCGUACGGAGGAGGGUGUC 21 15101 BCL11A-12857 - UGUGCGUACGGAGGAGGGUGUC 22 15102 BCL11A-12858 - GUGUGCGUACGGAGGAGGGUGUC 23 15103 BCL11A-12859 - GGUGUGCGUACGGAGGAGGGUGUC 24 15104 BCL11A-12860 - AAGUCUAAAAAACGAUUC 18 15105 BCL11A-12861 - CAAGUCUAAAAAACGAUUC 19 15106 BCL11A-12862 - ACAAGUCUAAAAAACGAUUC 20 15107 BCL11A-12863 - UACAAGUCUAAAAAACGAUUC 21 15108 BCL11A-12864 - GUACAAGUCUAAAAAACGAUUC 22 15109 BCL11A-12865 - AGUACAAGUCUAAAAAACGAUUC 23 15110 BCL11A-12866 - GAGUACAAGUCUAAAAAACGAUUC 24 15111 BCL11A-12867 - CUCCUCGGGCAAAGUUUC 18 15112 BCL11A-12868 - UCUCCUCGGGCAAAGUUUC 19 15113 BCL11A-12869 - CUCUCCUCGGGCAAAGUUUC 20 15114 BCL11A-12870 - CCUCUCCUCGGGCAAAGUUUC 21 15115 BCL11A-12871 - UCCUCUCCUCGGGCAAAGUUUC 22 15116 BCL11A-12872 - GUCCUCUCCUCGGGCAAAGUUUC 23 15117 BCL11A-12873 - UGUCCUCUCCUCGGGCAAAGUUUC 24 15118 BCL11A-12874 - UCACGGUCAAGUGUGCAG 18 15119 BCL11A-12875 - CUCACGGUCAAGUGUGCAG 19 15120 BCL11A-10145 - GCUCACGGUCAAGUGUGCAG 20 15121 BCL11A-12876 - CGCUCACGGUCAAGUGUGCAG 21 15122 BCL11A-12877 - GCGCUCACGGUCAAGUGUGCAG 22 15123 BCL11A-12878 - CGCGCUCACGGUCAAGUGUGCAG 23 15124 BCL11A-12879 - GCGCGCUCACGGUCAAGUGUGCAG 24 15125 BCL11A-12880 - UUCCCGGGGAGAAAAGAG 18 15126 BCL11A-12881 - AUUCCCGGGGAGAAAAGAG 19 15127 BCL11A-12882 - GAUUCCCGGGGAGAAAAGAG 20 15128 BCL11A-12883 - CGAUUCCCGGGGAGAAAAGAG 21 15129 BCL11A-12884 - ACGAUUCCCGGGGAGAAAAGAG 22 15130 BCL11A-12885 - AACGAUUCCCGGGGAGAAAAGAG 23 15131 BCL11A-12886 - AAACGAUUCCCGGGGAGAAAAGAG 24 15132 BCL11A-12887 - GCUCCUGAGUCCGCGGAG 18 15133 BCL11A-12888 - CGCUCCUGAGUCCGCGGAG 19 15134 BCL11A-12889 - GCGCUCCUGAGUCCGCGGAG 20 15135 BCL11A-12890 - GGCGCUCCUGAGUCCGCGGAG 21 15136 BCL11A-12891 - CGGCGCUCCUGAGUCCGCGGAG 22 15137 BCL11A-12892 - CCGGCGCUCCUGAGUCCGCGGAG 23 15138 BCL11A-12893 - CCCGGCGCUCCUGAGUCCGCGGAG 24 15139 BCL11A-12894 - AGUCCGCGGAGUCGGGAG 18 15140 BCL11A-12895 - GAGUCCGCGGAGUCGGGAG 19 15141 BCL11A-10150 - UGAGUCCGCGGAGUCGGGAG 20 15142 BCL11A-12896 - CUGAGUCCGCGGAGUCGGGAG 21 15143 BCL11A-12897 - CCUGAGUCCGCGGAGUCGGGAG 22 15144 BCL11A-12898 - UCCUGAGUCCGCGGAGUCGGGAG 23 15145 BCL11A-12899 - CUCCUGAGUCCGCGGAGUCGGGAG 24 15146 BCL11A-12900 - CGCGGCGGCGGCGGGGAG 18 15147 BCL11A-12901 - GCGCGGCGGCGGCGGGGAG 19 15148 BCL11A-10152 - AGCGCGGCGGCGGCGGGGAG 20 15149 BCL11A-12902 - GAGCGCGGCGGCGGCGGGGAG 21 15150 BCL11A-12903 - CGAGCGCGGCGGCGGCGGGGAG 22 15151 BCL11A-12904 - GCGAGCGCGGCGGCGGCGGGGAG 23 15152 BCL11A-12905 - AGCGAGCGCGGCGGCGGCGGGGAG 24 15153 BCL11A-11434 - CGCGUGUGUGGGGGGGAG 18 15154 BCL11A-11435 - CCGCGUGUGUGGGGGGGAG 19 15155 BCL11A-11436 - UCCGCGUGUGUGGGGGGGAG 20 15156 BCL11A-11437 - GUCCGCGUGUGUGGGGGGGAG 21 15157 BCL11A-11438 - AGUCCGCGUGUGUGGGGGGGAG 22 15158 BCL11A-11439 - GAGUCCGCGUGUGUGGGGGGGAG 23 15159 BCL11A-11440 - AGAGUCCGCGUGUGUGGGGGGGAG 24 15160 BCL11A-12906 - GCCCCUGGCGUCCACACG 18 15161 BCL11A-12907 - GGCCCCUGGCGUCCACACG 19 15162 BCL11A-10156 - CGGCCCCUGGCGUCCACACG 20 15163 BCL11A-12908 - UCGGCCCCUGGCGUCCACACG 21 15164 BCL11A-12909 - UUCGGCCCCUGGCGUCCACACG 22 15165 BCL11A-12910 - CUUCGGCCCCUGGCGUCCACACG 23 15166 BCL11A-12911 - ACUUCGGCCCCUGGCGUCCACACG 24 15167 BCL11A-12912 - AGAGGGGCCGCGGCGACG 18 15168 BCL11A-12913 - GAGAGGGGCCGCGGCGACG 19 15169 BCL11A-10158 - GGAGAGGGGCCGCGGCGACG 20 15170 BCL11A-12914 - GGGAGAGGGGCCGCGGCGACG 21 15171 BCL11A-12915 - CGGGAGAGGGGCCGCGGCGACG 22 15172 BCL11A-12916 - UCGGGAGAGGGGCCGCGGCGACG 23 15173 BCL11A-12917 - GUCGGGAGAGGGGCCGCGGCGACG 24 15174 BCL11A-12918 - GAAGUGGGUGUGCGUACG 18 15175 BCL11A-12919 - GGAAGUGGGUGUGCGUACG 19 15176 BCL11A-12920 - GGGAAGUGGGUGUGCGUACG 20 15177 BCL11A-12921 - GGGGAAGUGGGUGUGCGUACG 21 15178 BCL11A-12922 - AGGGGAAGUGGGUGUGCGUACG 22 15179 BCL11A-12923 - GAGGGGAAGUGGGUGUGCGUACG 23 15180 BCL11A-12924 - GGAGGGGAAGUGGGUGUGCGUACG 24 15181 BCL11A-12925 - UCUAAAAAACGAUUCCCG 18 15182 BCL11A-12926 - GUCUAAAAAACGAUUCCCG 19 15183 BCL11A-10164 - AGUCUAAAAAACGAUUCCCG 20 15184 BCL11A-12927 - AAGUCUAAAAAACGAUUCCCG 21 15185 BCL11A-12928 - CAAGUCUAAAAAACGAUUCCCG 22 15186 BCL11A-12929 - ACAAGUCUAAAAAACGAUUCCCG 23 15187 BCL11A-12930 - UACAAGUCUAAAAAACGAUUCCCG 24 15188 BCL11A-12931 - CGGCGACGGGGAGAGCCG 18 15189 BCL11A-12932 - GCGGCGACGGGGAGAGCCG 19 15190 BCL11A-10166 - CGCGGCGACGGGGAGAGCCG 20 15191 BCL11A-12933 - CCGCGGCGACGGGGAGAGCCG 21 15192 BCL11A-12934 - GCCGCGGCGACGGGGAGAGCCG 22 15193 BCL11A-12935 - GGCCGCGGCGACGGGGAGAGCCG 23 15194 BCL11A-12936 - GGGCCGCGGCGACGGGGAGAGCCG 24 15195 BCL11A-12937 - CCCUGGCGUCCACACGCG 18 15196 BCL11A-12938 - CCCCUGGCGUCCACACGCG 19 15197 BCL11A-10175 - GCCCCUGGCGUCCACACGCG 20 15198 BCL11A-12939 - GGCCCCUGGCGUCCACACGCG 21 15199 BCL11A-12940 - CGGCCCCUGGCGUCCACACGCG 22 15200 BCL11A-12941 - UCGGCCCCUGGCGUCCACACGCG 23 15201 BCL11A-12942 - UUCGGCCCCUGGCGUCCACACGCG 24 15202 BCL11A-12943 - GGGAGAGGGGCCGCGGCG 18 15203 BCL11A-12944 - CGGGAGAGGGGCCGCGGCG 19 15204 BCL11A-12945 - UCGGGAGAGGGGCCGCGGCG 20 15205 BCL11A-12946 - GUCGGGAGAGGGGCCGCGGCG 21 15206 BCL11A-12947 - AGUCGGGAGAGGGGCCGCGGCG 22 15207 BCL11A-12948 - GAGUCGGGAGAGGGGCCGCGGCG 23 15208 BCL11A-12949 - GGAGUCGGGAGAGGGGCCGCGGCG 24 15209 BCL11A-12950 - GGAGCGAGCGCGGCGGCG 18 15210 BCL11A-12951 - GGGAGCGAGCGCGGCGGCG 19 15211 BCL11A-12952 - GGGGAGCGAGCGCGGCGGCG 20 15212 BCL11A-12953 - CGGGGAGCGAGCGCGGCGGCG 21 15213 BCL11A-12954 - GCGGGGAGCGAGCGCGGCGGCG 22 15214 BCL11A-12955 - CGCGGGGAGCGAGCGCGGCGGCG 23 15215 BCL11A-12956 - ACGCGGGGAGCGAGCGCGGCGGCG 24 15216 BCL11A-12957 - GCGAGCGCGGCGGCGGCG 18 15217 BCL11A-12958 - AGCGAGCGCGGCGGCGGCG 19 15218 BCL11A-10179 - GAGCGAGCGCGGCGGCGGCG 20 15219 BCL11A-12959 - GGAGCGAGCGCGGCGGCGGCG 21 15220 BCL11A-12960 - GGGAGCGAGCGCGGCGGCGGCG 22 15221 BCL11A-12961 - GGGGAGCGAGCGCGGCGGCGGCG 23 15222 BCL11A-12962 - CGGGGAGCGAGCGCGGCGGCGGCG 24 15223 BCL11A-12963 - GCCGUGGGACCGGGAAGG 18 15224 BCL11A-12964 - AGCCGUGGGACCGGGAAGG 19 15225 BCL11A-12965 - GAGCCGUGGGACCGGGAAGG 20 15226 BCL11A-12966 - AGAGCCGUGGGACCGGGAAGG 21 15227 BCL11A-12967 - GAGAGCCGUGGGACCGGGAAGG 22 15228 BCL11A-12968 - GGAGAGCCGUGGGACCGGGAAGG 23 15229 BCL11A-12969 - GGGAGAGCCGUGGGACCGGGAAGG 24 15230 BCL11A-12970 - AGAAAAUGGGGGGGUAGG 18 15231 BCL11A-12971 - AAGAAAAUGGGGGGGUAGG 19 15232 BCL11A-12972 - UAAGAAAAUGGGGGGGUAGG 20 15233 BCL11A-12973 - GUAAGAAAAUGGGGGGGUAGG 21 15234 BCL11A-12974 - CGUAAGAAAAUGGGGGGGUAGG 22 15235 BCL11A-12975 - CCGUAAGAAAAUGGGGGGGUAGG 23 15236 BCL11A-12976 - ACCGUAAGAAAAUGGGGGGGUAGG 24 15237 BCL11A-12977 - AAGUGGGUGUGCGUACGG 18 15238 BCL11A-12978 - GAAGUGGGUGUGCGUACGG 19 15239 BCL11A-10191 - GGAAGUGGGUGUGCGUACGG 20 15240 BCL11A-12979 - GGGAAGUGGGUGUGCGUACGG 21 15241 BCL11A-12980 - GGGGAAGUGGGUGUGCGUACGG 22 15242 BCL11A-12981 - AGGGGAAGUGGGUGUGCGUACGG 23 15243 BCL11A-12982 - GAGGGGAAGUGGGUGUGCGUACGG 24 15244 BCL11A-12983 - CGGUCAAGUGUGCAGCGG 18 15245 BCL11A-12984 - ACGGUCAAGUGUGCAGCGG 19 15246 BCL11A-12985 - CACGGUCAAGUGUGCAGCGG 20 15247 BCL11A-12986 - UCACGGUCAAGUGUGCAGCGG 21 15248 BCL11A-12987 - CUCACGGUCAAGUGUGCAGCGG 22 15249 BCL11A-12988 - GCUCACGGUCAAGUGUGCAGCGG 23 15250 BCL11A-12989 - CGCUCACGGUCAAGUGUGCAGCGG 24 15251 BCL11A-12990 - GAGCGAGCGCGGCGGCGG 18 15252 BCL11A-12991 - GGAGCGAGCGCGGCGGCGG 19 15253 BCL11A-10196 - GGGAGCGAGCGCGGCGGCGG 20 15254 BCL11A-12992 - GGGGAGCGAGCGCGGCGGCGG 21 15255 BCL11A-12993 - CGGGGAGCGAGCGCGGCGGCGG 22 15256 BCL11A-12994 - GCGGGGAGCGAGCGCGGCGGCGG 23 15257 BCL11A-12995 - CGCGGGGAGCGAGCGCGGCGGCGG 24 15258 BCL11A-12996 - CUGAGUCCGCGGAGUCGG 18 15259 BCL11A-12997 - CCUGAGUCCGCGGAGUCGG 19 15260 BCL11A-12998 - UCCUGAGUCCGCGGAGUCGG 20 15261 BCL11A-12999 - CUCCUGAGUCCGCGGAGUCGG 21 15262 BCL11A-13000 - GCUCCUGAGUCCGCGGAGUCGG 22 15263 BCL11A-13001 - CGCUCCUGAGUCCGCGGAGUCGG 23 15264 BCL11A-13002 - GCGCUCCUGAGUCCGCGGAGUCGG 24 15265 BCL11A-13003 - gaaaauggggggguaggg 18 15266 BCL11A-13004 - AGAAAAUGGGGGGGUAGGG 19 15267 BCL11A-10200 - AAGAAAAUGGGGGGGUAGGG 20 15268 BCL11A-13005 - UAAGAAAAUGGGGGGGUAGGG 21 15269 BCL11A-13006 - GUAAGAAAAUGGGGGGGUAGGG 22 15270 BCL11A-13007 - CGUAAGAAAAUGGGGGGGUAGGG 23 15271 BCL11A-13008 - CCGUAAGAAAAUGGGGGGGUAGGG 24 15272 BCL11A-13009 - AGGGGCCGCGGCGACGGG 18 15273 BCL11A-13010 - GAGGGGCCGCGGCGACGGG 19 15274 BCL11A-13011 - AGAGGGGCCGCGGCGACGGG 20 15275 BCL11A-13012 - GAGAGGGGCCGCGGCGACGGG 21 15276 BCL11A-13013 - GGAGAGGGGCCGCGGCGACGGG 22 15277 BCL11A-13014 - GGGAGAGGGGCCGCGGCGACGGG 23 15278 BCL11A-13015 - CGGGAGAGGGGCCGCGGCGACGGG 24 15279 BCL11A-13016 - GAGAGCCGUGGGACCGGG 18 15280 BCL11A-13017 - GGAGAGCCGUGGGACCGGG 19 15281 BCL11A-13018 - GGGAGAGCCGUGGGACCGGG 20 15282 BCL11A-13019 - GGGGAGAGCCGUGGGACCGGG 21 15283 BCL11A-13020 - CGGGGAGAGCCGUGGGACCGGG 22 15284 BCL11A-13021 - ACGGGGAGAGCCGUGGGACCGGG 23 15285 BCL11A-13022 - GACGGGGAGAGCCGUGGGACCGGG 24 15286 BCL11A-13023 - UAAAAAACGAUUCCCGGG 18 15287 BCL11A-13024 - CUAAAAAACGAUUCCCGGG 19 15288 BCL11A-13025 - UCUAAAAAACGAUUCCCGGG 20 15289 BCL11A-13026 - GUCUAAAAAACGAUUCCCGGG 21 15290 BCL11A-13027 - AGUCUAAAAAACGAUUCCCGGG 22 15291 BCL11A-13028 - AAGUCUAAAAAACGAUUCCCGGG 23 15292 BCL11A-13029 - CAAGUCUAAAAAACGAUUCCCGGG 24 15293 BCL11A-13030 - GGUCAAGUGUGCAGCGGG 18 15294 BCL11A-13031 - CGGUCAAGUGUGCAGCGGG 19 15295 BCL11A-10202 - ACGGUCAAGUGUGCAGCGGG 20 15296 BCL11A-13032 - CACGGUCAAGUGUGCAGCGGG 21 15297 BCL11A-13033 - UCACGGUCAAGUGUGCAGCGGG 22 15298 BCL11A-13034 - CUCACGGUCAAGUGUGCAGCGGG 23 15299 BCL11A-13035 - GCUCACGGUCAAGUGUGCAGCGGG 24 15300 BCL11A-13036 - GAGCGCGGCGGCGGCGGG 18 15301 BCL11A-13037 - CGAGCGCGGCGGCGGCGGG 19 15302 BCL11A-13038 - GCGAGCGCGGCGGCGGCGGG 20 15303 BCL11A-13039 - AGCGAGCGCGGCGGCGGCGGG 21 15304 BCL11A-13040 - GAGCGAGCGCGGCGGCGGCGGG 22 15305 BCL11A-13041 - GGAGCGAGCGCGGCGGCGGCGGG 23 15306 BCL11A-13042 - GGGAGCGAGCGCGGCGGCGGCGGG 24 15307 BCL11A-13043 - AGCGCGGCGGCGGCGGGG 18 15308 BCL11A-13044 - GAGCGCGGCGGCGGCGGGG 19 15309 BCL11A-10206 - CGAGCGCGGCGGCGGCGGGG 20 15310 BCL11A-13045 - GCGAGCGCGGCGGCGGCGGGG 21 15311 BCL11A-13046 - AGCGAGCGCGGCGGCGGCGGGG 22 15312 BCL11A-13047 - GAGCGAGCGCGGCGGCGGCGGGG 23 15313 BCL11A-13048 - GGAGCGAGCGCGGCGGCGGCGGGG 24 15314 BCL11A-13049 - CGUAAGAAAAUGGGGGGG 18 15315 BCL11A-13050 - CCGUAAGAAAAUGGGGGGG 19 15316 BCL11A-13051 - ACCGUAAGAAAAUGGGGGGG 20 15317 BCL11A-13052 - CACCGUAAGAAAAUGGGGGGG 21 15318 BCL11A-13053 - UCACCGUAAGAAAAUGGGGGGG 22 15319 BCL11A-13054 - CUCACCGUAAGAAAAUGGGGGGG 23 15320 BCL11A-13055 - ACUCACCGUAAGAAAAUGGGGGGG 24 15321 BCL11A-13056 - CACAUGCAAACCUGGGGG 18 15322 BCL11A-13057 - UCACAUGCAAACCUGGGGG 19 15323 BCL11A-10210 - CUCACAUGCAAACCUGGGGG 20 15324 BCL11A-13058 - ACUCACAUGCAAACCUGGGGG 21 15325 BCL11A-13059 - AACUCACAUGCAAACCUGGGGG 22 15326 BCL11A-13060 - CAACUCACAUGCAAACCUGGGGG 23 15327 BCL11A-13061 - ACAACUCACAUGCAAACCUGGGGG 24 15328 BCL11A-13062 - UCACAUGCAAACCUGGGG 18 15329 BCL11A-13063 - CUCACAUGCAAACCUGGGG 19 15330 BCL11A-13064 - ACUCACAUGCAAACCUGGGG 20 15331 BCL11A-13065 - AACUCACAUGCAAACCUGGGG 21 15332 BCL11A-13066 - CAACUCACAUGCAAACCUGGGG 22 15333 BCL11A-13067 - ACAACUCACAUGCAAACCUGGGG 23 15334 BCL11A-13068 - AACAACUCACAUGCAAACCUGGGG 24 15335 BCL11A-11486 - GAGUCCGCGUGUGUGGGG 18 15336 BCL11A-11487 - AGAGUCCGCGUGUGUGGGG 19 15337 BCL11A-9577 - UAGAGUCCGCGUGUGUGGGG 20 15338 BCL11A-11488 - UUAGAGUCCGCGUGUGUGGGG 21 15339 BCL11A-11489 - UUUAGAGUCCGCGUGUGUGGGG 22 15340 BCL11A-11490 - UUUUAGAGUCCGCGUGUGUGGGG 23 15341 BCL11A-11491 - AUUUUAGAGUCCGCGUGUGUGGGG 24 15342 BCL11A-11492 - AGAGUCCGCGUGUGUGGG 18 15343 BCL11A-11493 - UAGAGUCCGCGUGUGUGGG 19 15344 BCL11A-9769 - UUAGAGUCCGCGUGUGUGGG 20 15345 BCL11A-11494 - UUUAGAGUCCGCGUGUGUGGG 21 15346 BCL11A-11495 - UUUUAGAGUCCGCGUGUGUGGG 22 15347 BCL11A-11496 - AUUUUAGAGUCCGCGUGUGUGGG 23 15348 BCL11A-11497 - CAUUUUAGAGUCCGCGUGUGUGGG 24 15349 BCL11A-13069 - CCUGGGGGUGGGAGCUGG 18 15350 BCL11A-13070 - ACCUGGGGGUGGGAGCUGG 19 15351 BCL11A-10217 - AACCUGGGGGUGGGAGCUGG 20 15352 BCL11A-13071 - AAACCUGGGGGUGGGAGCUGG 21 15353 BCL11A-13072 - CAAACCUGGGGGUGGGAGCUGG 22 15354 BCL11A-13073 - GCAAACCUGGGGGUGGGAGCUGG 23 15355 BCL11A-13074 - UGCAAACCUGGGGGUGGGAGCUGG 24 15356 BCL11A-11498 - UAGAGUCCGCGUGUGUGG 18 15357 BCL11A-11499 - UUAGAGUCCGCGUGUGUGG 19 15358 BCL11A-9578 - UUUAGAGUCCGCGUGUGUGG 20 15359 BCL11A-11500 - UUUUAGAGUCCGCGUGUGUGG 21 15360 BCL11A-11501 - AUUUUAGAGUCCGCGUGUGUGG 22 15361 BCL11A-11502 - CAUUUUAGAGUCCGCGUGUGUGG 23 15362 BCL11A-11503 - UCAUUUUAGAGUCCGCGUGUGUGG 24 15363 BCL11A-13075 - ACUCACCGUAAGAAAAUG 18 15364 BCL11A-13076 - CACUCACCGUAAGAAAAUG 19 15365 BCL11A-10221 - CCACUCACCGUAAGAAAAUG 20 15366 BCL11A-13077 - CCCACUCACCGUAAGAAAAUG 21 15367 BCL11A-13078 - UCCCACUCACCGUAAGAAAAUG 22 15368 BCL11A-13079 - UUCCCACUCACCGUAAGAAAAUG 23 15369 BCL11A-13080 - CUUCCCACUCACCGUAAGAAAAUG 24 15370 BCL11A-13081 - AGUGAGAAAGUGGCACUG 18 15371 BCL11A-13082 - UAGUGAGAAAGUGGCACUG 19 15372 BCL11A-10222 - AUAGUGAGAAAGUGGCACUG 20 15373 BCL11A-13083 - AAUAGUGAGAAAGUGGCACUG 21 15374 BCL11A-13084 - CAAUAGUGAGAAAGUGGCACUG 22 15375 BCL11A-13085 - ACAAUAGUGAGAAAGUGGCACUG 23 15376 BCL11A-13086 - CACAAUAGUGAGAAAGUGGCACUG 24 15377 BCL11A-13087 - ACCUGGGGGUGGGAGCUG 18 15378 BCL11A-13088 - AACCUGGGGGUGGGAGCUG 19 15379 BCL11A-13089 - AAACCUGGGGGUGGGAGCUG 20 15380 BCL11A-13090 - CAAACCUGGGGGUGGGAGCUG 21 15381 BCL11A-13091 - GCAAACCUGGGGGUGGGAGCUG 22 15382 BCL11A-13092 - UGCAAACCUGGGGGUGGGAGCUG 23 15383 BCL11A-13093 - AUGCAAACCUGGGGGUGGGAGCUG 24 15384 BCL11A-13094 - ACCUCCCCUCGCCCGCUG 18 15385 BCL11A-13095 - CACCUCCCCUCGCCCGCUG 19 15386 BCL11A-10224 - CCACCUCCCCUCGCCCGCUG 20 15387 BCL11A-13096 - CCCACCUCCCCUCGCCCGCUG 21 15388 BCL11A-13097 - UCCCACCUCCCCUCGCCCGCUG 22 15389 BCL11A-13098 - CUCCCACCUCCCCUCGCCCGCUG 23 15390 BCL11A-13099 - CCUCCCACCUCCCCUCGCCCGCUG 24 15391 BCL11A-13100 - UGGGGGUGGGAGCUGGUG 18 15392 BCL11A-13101 - CUGGGGGUGGGAGCUGGUG 19 15393 BCL11A-10228 - CCUGGGGGUGGGAGCUGGUG 20 15394 BCL11A-13102 - ACCUGGGGGUGGGAGCUGGUG 21 15395 BCL11A-13103 - AACCUGGGGGUGGGAGCUGGUG 22 15396 BCL11A-13104 - AAACCUGGGGGUGGGAGCUGGUG 23 15397 BCL11A-13105 - CAAACCUGGGGGUGGGAGCUGGUG 24 15398 BCL11A-11518 - UUUUAGAGUCCGCGUGUG 18 15399 BCL11A-11519 - AUUUUAGAGUCCGCGUGUG 19 15400 BCL11A-9581 - CAUUUUAGAGUCCGCGUGUG 20 15401 BCL11A-11520 - UCAUUUUAGAGUCCGCGUGUG 21 15402 BCL11A-11521 - UUCAUUUUAGAGUCCGCGUGUG 22 15403 BCL11A-11522 - UUUCAUUUUAGAGUCCGCGUGUG 23 15404 BCL11A-11523 - CUUUCAUUUUAGAGUCCGCGUGUG 24 15405 BCL11A-11524 - UUAGAGUCCGCGUGUGUG 18 15406 BCL11A-11525 - UUUAGAGUCCGCGUGUGUG 19 15407 BCL11A-9776 - UUUUAGAGUCCGCGUGUGUG 20 15408 BCL11A-11526 - AUUUUAGAGUCCGCGUGUGUG 21 15409 BCL11A-11527 - CAUUUUAGAGUCCGCGUGUGUG 22 15410 BCL11A-11528 - UCAUUUUAGAGUCCGCGUGUGUG 23 15411 BCL11A-11529 - UUCAUUUUAGAGUCCGCGUGUGUG 24 15412 BCL11A-13106 - CACUCACCGUAAGAAAAU 18 15413 BCL11A-13107 - CCACUCACCGUAAGAAAAU 19 15414 BCL11A-10232 - CCCACUCACCGUAAGAAAAU 20 15415 BCL11A-13108 - UCCCACUCACCGUAAGAAAAU 21 15416 BCL11A-13109 - UUCCCACUCACCGUAAGAAAAU 22 15417 BCL11A-13110 - CUUCCCACUCACCGUAAGAAAAU 23 15418 BCL11A-13111 - GCUUCCCACUCACCGUAAGAAAAU 24 15419 BCL11A-13112 - CGCUGCGGAGCUGUAACU 18 15420 BCL11A-13113 - CCGCUGCGGAGCUGUAACU 19 15421 BCL11A-10233 - CCCGCUGCGGAGCUGUAACU 20 15422 BCL11A-13114 - GCCCGCUGCGGAGCUGUAACU 21 15423 BCL11A-13115 - CGCCCGCUGCGGAGCUGUAACU 22 15424 BCL11A-13116 - UCGCCCGCUGCGGAGCUGUAACU 23 15425 BCL11A-13117 - CUCGCCCGCUGCGGAGCUGUAACU 24 15426 BCL11A-13118 - UAGUGAGAAAGUGGCACU 18 15427 BCL11A-13119 - AUAGUGAGAAAGUGGCACU 19 15428 BCL11A-13120 - AAUAGUGAGAAAGUGGCACU 20 15429 BCL11A-13121 - CAAUAGUGAGAAAGUGGCACU 21 15430 BCL11A-13122 - ACAAUAGUGAGAAAGUGGCACU 22 15431 BCL11A-13123 - CACAAUAGUGAGAAAGUGGCACU 23 15432 BCL11A-13124 - CCACAAUAGUGAGAAAGUGGCACU 24 15433 BCL11A-13125 - CGGUCCCUGGCUCGGCCU 18 15434 BCL11A-13126 - CCGGUCCCUGGCUCGGCCU 19 15435 BCL11A-10237 - CCCGGUCCCUGGCUCGGCCU 20 15436 BCL11A-13127 - CACCUCCCCUCGCCCGCU 18 15437 BCL11A-13128 - CCACCUCCCCUCGCCCGCU 19 15438 BCL11A-13129 - CCCACCUCCCCUCGCCCGCU 20 15439 BCL11A-13130 - UCCCACCUCCCCUCGCCCGCU 21 15440 BCL11A-13131 - CUCCCACCUCCCCUCGCCCGCU 22 15441 BCL11A-13132 - CCUCCCACCUCCCCUCGCCCGCU 23 15442 BCL11A-13133 - CCCUCCCACCUCCCCUCGCCCGCU 24 15443 BCL11A-13134 - CGAGCGCAGCCGCGGGCU 18 15444 BCL11A-13135 - CCGAGCGCAGCCGCGGGCU 19 15445 BCL11A-10241 - CCCGAGCGCAGCCGCGGGCU 20 15446 BCL11A-13136 - UCCCGAGCGCAGCCGCGGGCU 21 15447 BCL11A-13137 - UUCCCGAGCGCAGCCGCGGGCU 22 15448 BCL11A-13138 - UUUCCCGAGCGCAGCCGCGGGCU 23 15449 BCL11A-13139 - GUUUCCCGAGCGCAGCCGCGGGCU 24 15450 BCL11A-13140 - CUCCUGAGUCCGCGGAGU 18 15451 BCL11A-13141 - GCUCCUGAGUCCGCGGAGU 19 15452 BCL11A-10243 - CGCUCCUGAGUCCGCGGAGU 20 15453 BCL11A-13142 - GCGCUCCUGAGUCCGCGGAGU 21 15454 BCL11A-13143 - GGCGCUCCUGAGUCCGCGGAGU 22 15455 BCL11A-13144 - CGGCGCUCCUGAGUCCGCGGAGU 23 15456 BCL11A-13145 - CCGGCGCUCCUGAGUCCGCGGAGU 24 15457 BCL11A-13146 - AGUCAUCCCCACAAUAGU 18 15458 BCL11A-13147 - UAGUCAUCCCCACAAUAGU 19 15459 BCL11A-13148 - GUAGUCAUCCCCACAAUAGU 20 15460 BCL11A-13149 - AGUAGUCAUCCCCACAAUAGU 21 15461 BCL11A-13150 - AAGUAGUCAUCCCCACAAUAGU 22 15462 BCL11A-13151 - AAAGUAGUCAUCCCCACAAUAGU 23 15463 BCL11A-13152 - GAAAGUAGUCAUCCCCACAAUAGU 24 15464 BCL11A-13153 - UUGCUUCCCACUCACCGU 18 15465 BCL11A-13154 - GUUGCUUCCCACUCACCGU 19 15466 BCL11A-13155 - GGUUGCUUCCCACUCACCGU 20 15467 BCL11A-13156 - AGGUUGCUUCCCACUCACCGU 21 15468 BCL11A-13157 - GAGGUUGCUUCCCACUCACCGU 22 15469 BCL11A-13158 - GGAGGUUGCUUCCCACUCACCGU 23 15470 BCL11A-13159 - GGGAGGUUGCUUCCCACUCACCGU 24 15471 BCL11A-13160 - GGGGAAGUGGGUGUGCGU 18 15472 BCL11A-13161 - AGGGGAAGUGGGUGUGCGU 19 15473 BCL11A-13162 - GAGGGGAAGUGGGUGUGCGU 20 15474 BCL11A-13163 - GGAGGGGAAGUGGGUGUGCGU 21 15475 BCL11A-13164 - GGGAGGGGAAGUGGGUGUGCGU 22 15476 BCL11A-13165 - GGGGAGGGGAAGUGGGUGUGCGU 23 15477 BCL11A-13166 - CGGGGAGGGGAAGUGGGUGUGCGU 24 15478 BCL11A-13167 - GUAAGAAAAUGGGGGGGU 18 15479 BCL11A-13168 - CGUAAGAAAAUGGGGGGGU 19 15480 BCL11A-10248 - CCGUAAGAAAAUGGGGGGGU 20 15481 BCL11A-13169 - ACCGUAAGAAAAUGGGGGGGU 21 15482 BCL11A-13170 - CACCGUAAGAAAAUGGGGGGGU 22 15483 BCL11A-13171 - UCACCGUAAGAAAAUGGGGGGGU 23 15484 BCL11A-13172 - CUCACCGUAAGAAAAUGGGGGGGU 24 15485 BCL11A-13173 - ACAUGCAAACCUGGGGGU 18 15486 BCL11A-13174 - CACAUGCAAACCUGGGGGU 19 15487 BCL11A-10249 - UCACAUGCAAACCUGGGGGU 20 15488 BCL11A-13175 - CUCACAUGCAAACCUGGGGGU 21 15489 BCL11A-13176 - ACUCACAUGCAAACCUGGGGGU 22 15490 BCL11A-13177 - AACUCACAUGCAAACCUGGGGGU 23 15491 BCL11A-13178 - CAACUCACAUGCAAACCUGGGGGU 24 15492 BCL11A-13179 - CUGGGGGUGGGAGCUGGU 18 15493 BCL11A-13180 - CCUGGGGGUGGGAGCUGGU 19 15494 BCL11A-10250 - ACCUGGGGGUGGGAGCUGGU 20 15495 BCL11A-13181 - AACCUGGGGGUGGGAGCUGGU 21 15496 BCL11A-13182 - AAACCUGGGGGUGGGAGCUGGU 22 15497 BCL11A-13183 - CAAACCUGGGGGUGGGAGCUGGU 23 15498 BCL11A-13184 - GCAAACCUGGGGGUGGGAGCUGGU 24 15499 BCL11A-11572 - AUUUUAGAGUCCGCGUGU 18 15500 BCL11A-11573 - CAUUUUAGAGUCCGCGUGU 19 15501 BCL11A-11574 - UCAUUUUAGAGUCCGCGUGU 20 15502 BCL11A-11575 - UUCAUUUUAGAGUCCGCGUGU 21 15503 BCL11A-11576 - UUUCAUUUUAGAGUCCGCGUGU 22 15504 BCL11A-11577 - CUUUCAUUUUAGAGUCCGCGUGU 23 15505 BCL11A-11578 - UCUUUCAUUUUAGAGUCCGCGUGU 24 15506 BCL11A-13185 - GCGUACGGAGGAGGGUGU 18 15507 BCL11A-13186 - UGCGUACGGAGGAGGGUGU 19 15508 BCL11A-13187 - GUGCGUACGGAGGAGGGUGU 20 15509 BCL11A-13188 - UGUGCGUACGGAGGAGGGUGU 21 15510 BCL11A-13189 - GUGUGCGUACGGAGGAGGGUGU 22 15511 BCL11A-13190 - GGUGUGCGUACGGAGGAGGGUGU 23 15512 BCL11A-13191 - GGGUGUGCGUACGGAGGAGGGUGU 24 15513 BCL11A-11579 - UUUAGAGUCCGCGUGUGU 18 15514 BCL11A-11580 - UUUUAGAGUCCGCGUGUGU 19 15515 BCL11A-9586 - AUUUUAGAGUCCGCGUGUGU 20 15516 BCL11A-11581 - CAUUUUAGAGUCCGCGUGUGU 21 15517 BCL11A-11582 - UCAUUUUAGAGUCCGCGUGUGU 22 15518 BCL11A-11583 - UUCAUUUUAGAGUCCGCGUGUGU 23 15519 BCL11A-11584 - UUUCAUUUUAGAGUCCGCGUGUGU 24 15520 BCL11A-13192 - GACUUGGGCGCUGCCCUU 18 15521 BCL11A-13193 - AGACUUGGGCGCUGCCCUU 19 15522 BCL11A-13194 - GAGACUUGGGCGCUGCCCUU 20 15523 BCL11A-13195 - GGAGACUUGGGCGCUGCCCUU 21 15524 BCL11A-13196 - UGGAGACUUGGGCGCUGCCCUU 22 15525 BCL11A-13197 - CUGGAGACUUGGGCGCUGCCCUU 23 15526 BCL11A-13198 - CCUGGAGACUUGGGCGCUGCCCUU 24 15527 BCL11A-13199 - GGUCCCUGGCUCGGCCUU 18 15528 BCL11A-13200 - CGGUCCCUGGCUCGGCCUU 19 15529 BCL11A-10256 - CCGGUCCCUGGCUCGGCCUU 20 15530 BCL11A-13201 - AAGAGGUGAGACUGGCUU 18 15531 BCL11A-13202 - AAAGAGGUGAGACUGGCUU 19 15532 BCL11A-13203 - AAAAGAGGUGAGACUGGCUU 20 15533 BCL11A-13204 - GAAAAGAGGUGAGACUGGCUU 21 15534 BCL11A-13205 - AGAAAAGAGGUGAGACUGGCUU 22 15535 BCL11A-13206 - GAGAAAAGAGGUGAGACUGGCUU 23 15536 BCL11A-13207 - GGAGAAAAGAGGUGAGACUGGCUU 24 15537 BCL11A-13208 - AUGAACAAUGCUAAGGUU 18 15538 BCL11A-13209 - AAUGAACAAUGCUAAGGUU 19 15539 BCL11A-13210 - UAAUGAACAAUGCUAAGGUU 20 15540 BCL11A-13211 - AUAAUGAACAAUGCUAAGGUU 21 15541 BCL11A-13212 - AAUAAUGAACAAUGCUAAGGUU 22 15542 BCL11A-13213 - AAAUAAUGAACAAUGCUAAGGUU 23 15543 BCL11A-13214 - AAAAUAAUGAACAAUGCUAAGGUU 24 15544 BCL11A-13215 - GCCGCUUUAUUUCUCUUU 18 15545 BCL11A-13216 - CGCCGCUUUAUUUCUCUUU 19 15546 BCL11A-13217 - CCGCCGCUUUAUUUCUCUUU 20 15547 BCL11A-13218 - UCCGCCGCUUUAUUUCUCUUU 21 15548 BCL11A-13219 - UUCCGCCGCUUUAUUUCUCUUU 22 15549 BCL11A-13220 - UUUCCGCCGCUUUAUUUCUCUUU 23 15550 BCL11A-13221 - CUUUCCGCCGCUUUAUUUCUCUUU 24 15551

Table 20A provides exemplary targeting domains for knocking down the BCL11A gene selected according to the first tier parameters. The targeting domains bind within 500 bp (e.g., upstream or downstream) of a transcription start site (TSS) and have a high level of orthogonality. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL17A gene (e.g., reduce or eliminate BCL11A gene expression, BCL11A protein function, or the level of BCL15A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 20A 1st Tier Target DNA Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-13222 + ACACACCCCUCUCUCCC 17 15552 BCL11A-9477 + CUUACGCGAGAAUUCCC 17 15553 BCL11A-13223 + CCCUCUCUCCCCCUCGC 17 15554 BCL11A-13224 + UCUAGUCCUGCGCGCUC 17 15555 BCL11A-9638 - UUGAACUUGCAGCUCAG 17 15556 BCL11A-9482 + UUAAGUGCUGGGGUUUG 17 15557 BCL11A-13225 + CACGCGGACUCUAAAAU 17 15558 BCL11A-13226 + AAUUGUGGGAGAGCCGU 17 15559 BCL11A-13227 - GAUGUGUGUCCAUUGGU 17 15560 BCL11A-13228 + UGCACACACCCCUCUCUCCC 20 15561 BCL11A-9487 + UUACUUACGCGAGAAUUCCC 20 15562 BCL11A-13229 + CACCCCUCUCUCCCCCUCGC 20 15563 BCL11A-13230 + GCUUCUAGUCCUGCGCGCUC 20 15564 BCL11A-9738 - CACUUGAACUUGCAGCUCAG 20 15565 BCL11A-9491 + UGCUUAAGUGCUGGGGUUUG 20 15566 BCL11A-13231 + AUGAAUUGUGGGAGAGCCGU 20 15567 BCL11A-11567 - CCUGAUGUGUGUCCAUUGGU 20 15568

Table 20B provides exemplary targeting domains for knocking down the BCL11A gene selected according to the second tier parameters. The targeting domains bind within 500 bp (e.g., upstream or downstream) of a transcription start site (TSS). It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL11A protein function, or the level of BCL11A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 20B 2nd Tier DNA Target Site SEQ gRNA Name Strand Targeting Domain Length ID NO: BCL11A-13232 - CCCUCCCCGCACUGGCC 17 15569 BCL11A-13233 - UUUUUUUUUUUUUUUUU 17 15570 BCL11A-13234 - UCCCCCUCCCCGCACUGGCC 20 15571 BCL11A-13235 + ACACACGCGGACUCUAAAAU 20 15572 BCL11A-13236 - UUUUUUUUUUUUUUUUUUUU 20 15573

Table 20C provides exemplary targeting domains for knocking down the BCL11A gene selected according to the third tier parameters. The targeting domains bind within the additional 500 bp (e.g., upstream or downstream) of a transcription start site (TSS), e.g., extending to 1 kb upstream and downstream of a TSS. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis eiCas9 molecule or eiCas9 fusion protein (e.g., an eiCas9 fused to a transcription repressor domain) to alter the BCL11A gene (e.g., reduce or eliminate BCL11A gene expression, BCL15A protein function, or the level of BCL11A protein). One or more gRNA may be used to target an eiCas9 to the promoter region of the BCL11A gene.

TABLE 20C 3rd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length NO: BCL11A-13237 - GUGAGUACAAGUCUAAA 17 15574 BCL11A-13238 - GCUGGUGGGGAAAGGGA 17 15575 BCL11A-13239 - GUCCGGGAGCAACUCUA 17 15576 BCL11A-13240 - CCUUUUGUGCCGGCUCC 17 15577 BCL11A-13241 - ACCUGGCUUCCCUCCGC 17 15578 BCL11A-9896 - GCUCAGCUCUCAACUUC 17 15579 BCL11A-13242 - UCCUCUUUCCUCCUUUC 17 15580 BCL11A-13243 - GGGAGAAAAGAGGUGAG 17 15581 BCL11A-13244 - CAGCCCUCCAAACUUAG 17 15582 BCL11A-13245 - CUUUUCGAAAAGGAAUG 17 15583 BCL11A-13225 + CACGCGGACUCUAAAAU 17 15584 BCL11A-10006 - GAGCGCAGCCGCGGGCU 17 15585 BCL11A-13246 - GGAGUGAGUACAAGUCUAAA 20 15586 BCL11A-13247 - GGAGCUGGUGGGGAAAGGGA 20 15587 BCL11A-13248 - GGUGUCCGGGAGCAACUCUA 20 15588 BCL11A-13249 - CUGCCUUUUGUGCCGGCUCC 20 15589 BCL11A-13250 - UCUACCUGGCUUCCCUCCGC 20 15590 BCL11A-10131 - GAGGCUCAGCUCUCAACUUC 20 15591 BCL11A-13251 - uccuccucuuuccuccuuuc 20 15592 BCL11A-13252 - CCGGGGAGAAAAGAGGUGAG 20 15593 BCL11A-13253 - CCGCAGCCCUCCAAACUUAG 20 15594 BCL11A-13254 - UCUCUUUUCGAAAAGGAAUG 20 15595 BCL11A-13235 + ACACACGCGGACUCUAAAAU 20 15596 BCL11A-10241 - CCCGAGCGCAGCCGCGGGCU 20 15597

Table 21A provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), and have a high level of orthogonality and starts with 5′G. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 21A 1st Tier Target DNA Site SEQ ID gRNA Name Strand Targeting Domain Length 5′ or 3′ NO: BCL11A-13255 + GCACUAGGUGAAAUCUC 17 5′ 15598 BCL11A-13256 - GAAAGCAGUGUAAGGCU 17 5′ 15599 BCL11A-13257 - GUAAUUAAGAAAGCAGUGUA 20 5′ 15600 BCL11A-13258 + GUUGCACUAGGUGAAAUCUC 20 5′ 15601 BCL11A-13259 - GGCUGUUUUGGAAUGUAGAG 20 5′ 15602 BCL11A-13260 - GGCUGUUUUUGGAUCUU 17 3′ 15603 BCL11A-13261 + GUGCUACUUAUACAAUUCAC 20 3′ 15604 BCL11A-13262 + GAAAAUACUUACUGUACUGC 20 3′ 15605

Table 21B provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the second tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) and have a high level of orthogonality. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 21B 2nd Tier Target DNA Site SEQ ID gRNA Name Strand Targeting Domain Length 5′ or 3′ NO: BCL11A-13263 - AUUAAGAAAGCAGUGUA 17 5′ 15606 BCL11A-13264 + AUUUUACUAGUGAAUUA 17 5′ 15607 BCL11A-13265 + AUUUAAGACGGGAAAAC 17 5′ 15608 BCL11A-13266 - AGAAAGCAGUGUAAGGC 17 5′ 15609 BCL11A-13267 - UGUUUUGGAAUGUAGAG 17 5′ 15610 BCL11A-13268 + ACAACUUGUGUUGCACU 17 5′ 15611 BCL11A-13269 + UCUCACAUAAAAAUUUAAGA 20 5′ 15612 BCL11A-13270 - UUGGAAUGUAGAGAGGCAGA 20 5′ 15613 BCL11A-13271 + AUUAUUUUACUAGUGAAUUA 20 5′ 15614 BCL11A-13272 + AAAAUUUAAGACGGGAAAAC 20 5′ 15615 BCL11A-13273 + CUCACAUAAAAAUUUAAGAC 20 5′ 15616 BCL11A-13274 + UACACAACUUGUGUUGCACU 20 5′ 15617 BCL11A-13275 - UAAGAAAGCAGUGUAAGGCU 20 5′ 15618 BCL11A-13276 - AUUAGAAUAAAAGGCUGUUU 20 5′ 15619 BCL11A-13277 - UAUUUACAGCCAUAACA 17 3′ 15620 BCL11A-13278 + AUACUUACUGUACUGCA 17 3′ 15621 BCL11A-13279 + CACUGGAAACCCUGUUA 17 3′ 15622 BCL11A-13280 - CUAUUUACAGCCAUAAC 17 3′ 15623 BCL11A-13281 + CUACUUAUACAAUUCAC 17 3′ 15624 BCL11A-13282 + AAUACUUACUGUACUGC 17 3′ 15625 BCL11A-13283 + UACUUACUGUACUGCAG 17 3′ 15626 BCL11A-13284 + UGUACUGCAGGGGAAUU 17 3′ 15627 BCL11A-13285 - UGGGUAGCAGUGGCUUU 17 3′ 15628 BCL11A-13286 - UGGCUUUAGGCUGUUUU 17 3′ 15629 BCL11A-13287 - AACUAUUUACAGCCAUAACA 20 3′ 15630 BCL11A-13288 + AAAAUACUUACUGUACUGCA 20 3′ 15631 BCL11A-13289 + AUUCACUGGAAACCCUGUUA 20 3′ 15632 BCL11A-13290 - AAACUAUUUACAGCCAUAAC 20 3′ 15633 BCL11A-13291 + AAAUACUUACUGUACUGCAG 20 3′ 15634 BCL11A-13292 + UACUGUACUGCAGGGGAAUU 20 3′ 15635 BCL11A-13293 - UUAGGCUGUUUUUGGAUCUU 20 3′ 15636 BCL11A-13294 - CAGUGGCUUUAGGCUGUUUU 20 3′ 15637

Table 21C provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the third tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) and starts with 5′G. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 21C 3rd Tier DNA Target Site SEQ ID gRNA Name Strand Targeting Domain Length 5′ or 3′ NO: BCL11A-13295 - GAAUGUAGAGAGGCAGA 17 5′ 15638 BCL11A-13296 - GGAAUGUAGAGAGGCAG 17 5′ 15639 BCL11A-13297 - GUAUUUUCUUUCAUUGG 17 3′ 15640 BCL11A-13298 - GUAAGUAUUUUCUUUCAUUG 20 3′ 15641

Table 21D provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the fourth tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS). It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 21D 4th Tier Target DNA Site SEQ ID gRNA Name Strand Targeting Domain Length 5′ or 3′ NO: BCL11A-13299 - AAAAUAAUUAGAAUAAA 17 5′ 15642 BCL11A-13300 + CACAUAAAAAUUUAAGA 17 5′ 15643 BCL11A-13301 + ACAUAAAAAUUUAAGAC 17 5′ 15644 BCL11A-13302 - UGUAAGGCUGGGCGCAG 17 5′ 15645 BCL11A-13303 - AAUGUAGAGAGGCAGAG 17 5′ 15646 BCL11A-13304 - AGAAUAAAAGGCUGUUU 17 5′ 15647 BCL11A-13305 - AGUAAAAUAAUUAGAAUAAA 20 5′ 15648 BCL11A-13306 - UUAAGAAAGCAGUGUAAGGC 20 5′ 15649 BCL11A-13307 - CAGUGUAAGGCUGGGCGCAG 20 5′ 15650 BCL11A-13308 - UUUGGAAUGUAGAGAGGCAG 20 5′ 15651 BCL11A-13309 - UGGAAUGUAGAGAGGCAGAG 20 5′ 15652 BCL11A-13310 - AGUAUUUUCUUUCAUUG 17 3′ 15653 BCL11A-13311 - UAAGUAUUUUCUUUCAU 17 3′ 15654 BCL11A-13312 - AAGUAUUUUCUUUCAUU 17 3′ 15655 BCL11A-13313 - UAAGUAUUUUCUUUCAUUGG 20 3′ 15656 BCL11A-13314 - CAGUAAGUAUUUUCUUUCAU 20 3′ 15657 BCL11A-13315 - AGUAAGUAUUUUCUUUCAUU 20 3′ 15658

Table 21E provides targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene by dual targeting (e.g., dual double strand cleavage). It is contemplated herein that an upstream gRNA can be paired with a downstream gRNA to guide Cas9 nuclease pairs. Exemplary nickase pairs include a targeting domain from Group A and a second targeting domain from Group B, or include a targeting domain from Group C and a second targeting domain from Group D. It is contemplated herein that in an embodiment a targeting domain of Group A can be combined with any of the targeting domains of Group B; in an embodiment a targeting domain of Group C can be combined with any of the targeting domains of Group D. For example, BCL11A-13271 or BCL11A-13264 can be combined with BCL11A-13276; or BCL11A-13262 or BCL11A-13282 can be combined with BCL11A-13290 or BCL11A-13280.

TABLE 21E Group A Group B BCL11A-13271, BCL11A- BCL11A-13276 13264 Group C Group D BCL11A-13262, BCL11A- BCL11A-13290, BCL11A- 13282 13280

Table 22A provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), have a high level of orthogonality, and start with 5′G. The PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 22A 1st Tier Target SEQ DNA Site 5′ ID gRNA Name Strand Targeting Domain Length or 3′ NO: BCL11A-13316 − GGGGCUGAUAUAACUUCU 18 5′ 15659 BCL11A-13317 − GAGGGGCUGAUAUAACUUCU 20 5′ 15660 BCL11A-13318 − GCAGAGGGGCUGAUAUAACUUCU 23 5′ 15661 BCL11A-13319 − GGCAGAGGGGCUGAUAUAACUUCU 24 5′ 15662 BCL11A-13320 − GCAAACUAUUUACAGCCAUAA 21 3′ 15663 BCL11A-13321 − GAAGCAAACUAUUUACAGCCAUAA 24 3′ 15664 BCL11A-13322 − GCCAUAACAGGGUUUCCA 18 3′ 15665 BCL11A-13323 − GUGAAUUGUAUAAGUAGCA 19 3′ 15666 BCL11A-13324 − GCAAAACUAGAAAGUUUUA 19 3′ 15667 BCL11A-13325 − GCAGUGGCUUUAGGCUGUUU 20 3′ 15668 BCL11A-13326 − GUAGCAGUGGCUUUAGGCUGUUU 23 3′ 15669 BCL11A-13327 − GGUAGCAGUGGCUUUAGGCUGUUU 24 3′ 15670

Table 22B provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the second tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), and have a high level of orthogonality. The PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 22B 2nd Tier Target SEQ DNA Site 5′ ID gRNA Name Strand Targeting Domain Length or 3′ NO: BCL11A-13328 + UUUAUUCUAAUUAUUUUACUA 21 5′ 15671 BCL11A-13329 + UUUUAUUCUAAUUAUUUUACUA 22 5′ 15672 BCL11A-13330 + CUUUUAUUCUAAUUAUUUUACUA 23 5′ 15673 BCL11A-13331 + CCUUUUAUUCUAAUUAUUUUACUA 24 5′ 15674 BCL11A-13332 + UAUUUUACUAGUGAAUUA 18 5′ 15675 BCL11A-13333 + UUAUUUUACUAGUGAAUUA 19 5′ 15676 BCL11A-13334 + AUUAUUUUACUAGUGAAUUA 20 5′ 15677 BCL11A-13335 + AAUUAUUUUACUAGUGAAUUA 21 5′ 15678 BCL11A-13336 + UAAUUAUUUUACUAGUGAAUUA 22 5′ 15679 BCL11A-13337 + CUAAUUAUUUUACUAGUGAAUUA 23 5′ 15680 BCL11A-13338 + UCUAAUUAUUUUACUAGUGAAUUA 24 5′ 15681 BCL11A-13339 − AUUCACUAGUAAAAUAAU 18 5′ 15682 BCL11A-13340 − AAUUCACUAGUAAAAUAAU 19 5′ 15683 BCL11A-13341 − UAAUUCACUAGUAAAAUAAU 20 5′ 15684 BCL11A-13342 − AGGGGCUGAUAUAACUUCU 19 5′ 15685 BCL11A-13343 − AGAGGGGCUGAUAUAACUUCU 21 5′ 15686 BCL11A-13344 − CAGAGGGGCUGAUAUAACUUCU 22 5′ 15687 BCL11A-13345 − UAGAAUAAAAGGCUGUUU 18 5′ 15688 BCL11A-13346 − UUAGAAUAAAAGGCUGUUU 19 5′ 15689 BCL11A-13347 − AUUAGAAUAAAAGGCUGUUU 20 5′ 15690 BCL11A-13348 − AAUUAGAAUAAAAGGCUGUUU 21 5′ 15691 BCL11A-13349 − UAAUUAGAAUAAAAGGCUGUUU 22 5′ 15692 BCL11A-13350 − AUAAUUAGAAUAAAAGGCUGUUU 23 5′ 15693 BCL11A-13351 − AAUAAUUAGAAUAAAAGGCUGUUU 24 5′ 15694 BCL11A-13352 + AUACUUACUGUACUGCAG 18 3′ 15695 BCL11A-13353 + AAUACUUACUGUACUGCAG 19 3′ 15696 BCL11A-13354 + AAAUACUUACUGUACUGCAG 20 3′ 15697 BCL11A-13355 − AACUAUUUACAGCCAUAA 18 3′ 15698 BCL11A-13356 − AAACUAUUUACAGCCAUAA 19 3′ 15699 BCL11A-13357 − CAAACUAUUUACAGCCAUAA 20 3′ 15700 BCL11A-13358 − AGCAAACUAUUUACAGCCAUAA 22 3′ 15701 BCL11A-13359 − AAGCAAACUAUUUACAGCCAUAA 23 3′ 15702 BCL11A-13360 − AGCCAUAACAGGGUUUCCA 19 3′ 15703 BCL11A-13361 − CAGCCAUAACAGGGUUUCCA 20 3′ 15704 BCL11A-13362 − ACAGCCAUAACAGGGUUUCCA 21 3′ 15705 BCL11A-13363 − UACAGCCAUAACAGGGUUUCCA 22 3′ 15706 BCL11A-13364 − UUACAGCCAUAACAGGGUUUCCA 23 3′ 15707 BCL11A-13365 − UUUACAGCCAUAACAGGGUUUCCA 24 3′ 15708 BCL11A-13366 − UGAAUUGUAUAAGUAGCA 18 3′ 15709 BCL11A-13367 − AGUGAAUUGUAUAAGUAGCA 20 3′ 15710 BCL11A-13368 − CAGUGAAUUGUAUAAGUAGCA 21 3′ 15711 BCL11A-13369 − CCAGUGAAUUGUAUAAGUAGCA 22 3′ 15712 BCL11A-13370 − UCCAGUGAAUUGUAUAAGUAGCA 23 3′ 15713 BCL11A-13371 − UUCCAGUGAAUUGUAUAAGUAGCA 24 3′ 15714 BCL11A-13372 − CAAAACUAGAAAGUUUUA 18 3′ 15715 BCL11A-13373 − AGCAAAACUAGAAAGUUUUA 20 3′ 15716 BCL11A-13374 − AGUGGCUUUAGGCUGUUU 18 3′ 15717 BCL11A-13375 − CAGUGGCUUUAGGCUGUUU 19 3′ 15718 BCL11A-13376 − AGCAGUGGCUUUAGGCUGUUU 21 3′ 15719 BCL11A-13377 − UAGCAGUGGCUUUAGGCUGUUU 22 3′ 15720

Table 22C provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the third tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), and start with 5′G. The PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 22C 3rd Tier Target SEQ DNA Site 5′ ID gRNA Name Strand Targeting Domain Length or 3′ NO: BCL11A-13378 + GAAAAUACUUACUGUACUGCAG 22 3′ 15721 BCL11A-13379 − GUUAAGCAAAACUAGAAAGUUUUA 24 3′ 15722

Table 22D provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the second tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), and the PAM is NNGRRT. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 22D 4th Tier Target SEQ DNA Site 5′ ID gRNA Name Strand Targeting Domain Length or 3′ NO: BCL11A-13380 + AUUCUAAUUAUUUUACUA 18 5′ 15723 BCL11A-13381 + UAUUCUAAUUAUUUUACUA 19 5′ 15724 BCL11A-13382 + UUAUUCUAAUUAUUUUACUA 20 5′ 15725 BCL11A-13383 − AUAAUUCACUAGUAAAAUAAU 21 5′ 15726 BCL11A-13384 − CAUAAUUCACUAGUAAAAUAAU 22 5′ 15727 BCL11A-13385 − CCAUAAUUCACUAGUAAAAUAAU 23 5′ 15728 BCL11A-13386 − UCCAUAAUUCACUAGUAAAAUAAU 24 5′ 15729 BCL11A-13387 + AAAAUACUUACUGUACUGCAG 21 3′ 15730 BCL11A-13388 + AGAAAAUACUUACUGUACUGCAG 23 3′ 15731 BCL11A-13389 + AAGAAAAUACUUACUGUACUGCAG 24 3′ 15732 BCL11A-13390 − AAGCAAAACUAGAAAGUUUUA 21 3′ 15733 BCL11A-13391 − UAAGCAAAACUAGAAAGUUUUA 22 3′ 15734 BCL11A-13392 − UUAAGCAAAACUAGAAAGUUUUA 23 3′ 15735

Table 22E provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the third tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), and the PAM is NNGRRV. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. aureus Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 22E 5th Tier Target SEQ DNA Site 5′ ID gRNA Name Strand Targeting Domain Length or 3′ NO: BCL11A-13393 + AAAUUUAAGACGGGAAAA 18 5′ 15736 BCL11A-13394 + AAAAUUUAAGACGGGAAAA 19 5′ 15737 BCL11A-13395 + AAAAAUUUAAGACGGGAAAA 20 5′ 15738 BCL11A-13396 + UAAAAAUUUAAGACGGGAAAA 21 5′ 15739 BCL11A-13397 + AUAAAAAUUUAAGACGGGAAAA 22 5′ 15740 BCL11A-13398 + CAUAAAAAUUUAAGACGGGAAAA 23 5′ 15741 BCL11A-13399 + ACAUAAAAAUUUAAGACGGGAAAA 24 5′ 15742 BCL11A-13400 + UCACAUAAAAAUUUAAGA 18 5′ 15743 BCL11A-13401 + CUCACAUAAAAAUUUAAGA 19 5′ 15744 BCL11A-13402 + UCUCACAUAAAAAUUUAAGA 20 5′ 15745 BCL11A-13403 + AUCUCACAUAAAAAUUUAAGA 21 5′ 15746 BCL11A-13404 + CAUCUCACAUAAAAAUUUAAGA 22 5′ 15747 BCL11A-13405 + UCAUCUCACAUAAAAAUUUAAGA 23 5′ 15748 BCL11A-13406 + CUCAUCUCACAUAAAAAUUUAAGA 24 5′ 15749 BCL11A-13407 + AAUUUAAGACGGGAAAAC 18 5′ 15750 BCL11A-13408 + AAAUUUAAGACGGGAAAAC 19 5′ 15751 BCL11A-13409 + AAAAUUUAAGACGGGAAAAC 20 5′ 15752 BCL11A-13410 + AAAAAUUUAAGACGGGAAAAC 21 5′ 15753 BCL11A-13411 + UAAAAAUUUAAGACGGGAAAAC 22 5′ 15754 BCL11A-13412 + AUAAAAAUUUAAGACGGGAAAAC 23 5′ 15755 BCL11A-13413 + CAUAAAAAUUUAAGACGGGAAAAC 24 5′ 15756 BCL11A-13414 + CACAUAAAAAUUUAAGAC 18 5′ 15757 BCL11A-13415 + UCACAUAAAAAUUUAAGAC 19 5′ 15758 BCL11A-13416 + CUCACAUAAAAAUUUAAGAC 20 5′ 15759 BCL11A-13417 + UCUCACAUAAAAAUUUAAGAC 21 5′ 15760 BCL11A-13418 + AUCUCACAUAAAAAUUUAAGAC 22 5′ 15761 BCL11A-13419 + CAUCUCACAUAAAAAUUUAAGAC 23 5′ 15762 BCL11A-13420 + UCAUCUCACAUAAAAAUUUAAGAC 24 5′ 15763 BCL11A-13421 + CUCACAUAAAAAUUUAAG 18 5′ 15764 BCL11A-13422 + UCUCACAUAAAAAUUUAAG 19 5′ 15765 BCL11A-13423 + AUCUCACAUAAAAAUUUAAG 20 5′ 15766 BCL11A-13424 + CAUCUCACAUAAAAAUUUAAG 21 5′ 15767 BCL11A-13425 + UCAUCUCACAUAAAAAUUUAAG 22 5′ 15768 BCL11A-13426 + CUCAUCUCACAUAAAAAUUUAAG 23 5′ 15769 BCL11A-13427 + GCUCAUCUCACAUAAAAAUUUAAG 24 5′ 15770 BCL11A-13428 + CAACUUGUGUUGCACUAG 18 5′ 15771 BCL11A-13429 + ACAACUUGUGUUGCACUAG 19 5′ 15772 BCL11A-13430 + CACAACUUGUGUUGCACUAG 20 5′ 15773 BCL11A-13431 + ACACAACUUGUGUUGCACUAG 21 5′ 15774 BCL11A-13432 + UACACAACUUGUGUUGCACUAG 22 5′ 15775 BCL11A-13433 + CUACACAACUUGUGUUGCACUAG 23 5′ 15776 BCL11A-13434 + UCUACACAACUUGUGUUGCACUAG 24 5′ 15777 BCL11A-13435 + AACAGGAAGAUGCAUUCU 18 5′ 15778 BCL11A-13436 + AAACAGGAAGAUGCAUUCU 19 5′ 15779 BCL11A-13437 + AAAACAGGAAGAUGCAUUCU 20 5′ 15780 BCL11A-13438 + GAAAACAGGAAGAUGCAUUCU 21 5′ 15781 BCL11A-13439 + GGAAAACAGGAAGAUGCAUUCU 22 5′ 15782 BCL11A-13440 + GGGAAAACAGGAAGAUGCAUUCU 23 5′ 15783 BCL11A-13441 + CGGGAAAACAGGAAGAUGCAUUCU 24 5′ 15784 BCL11A-13442 + UUAUUUUACUAGUGAAUU 18 5′ 15785 BCL11A-13443 + AUUAUUUUACUAGUGAAUU 19 5′ 15786 BCL11A-13444 + AAUUAUUUUACUAGUGAAUU 20 5′ 15787 BCL11A-13445 + UAAUUAUUUUACUAGUGAAUU 21 5′ 15788 BCL11A-13446 + CUAAUUAUUUUACUAGUGAAUU 22 5′ 15789 BCL11A-13447 + UCUAAUUAUUUUACUAGUGAAUU 23 5′ 15790 BCL11A-13448 + UUCUAAUUAUUUUACUAGUGAAUU 24 5′ 15791 BCL11A-13449 + AAAACAGGAAGAUGCAUU 18 5′ 15792 BCL11A-13450 + GAAAACAGGAAGAUGCAUU 19 5′ 15793 BCL11A-13451 + GGAAAACAGGAAGAUGCAUU 20 5′ 15794 BCL11A-13452 + GGGAAAACAGGAAGAUGCAUU 21 5′ 15795 BCL11A-13453 + CGGGAAAACAGGAAGAUGCAUU 22 5′ 15796 BCL11A-13454 + ACGGGAAAACAGGAAGAUGCAUU 23 5′ 15797 BCL11A-13455 + GACGGGAAAACAGGAAGAUGCAUU 24 5′ 15798 BCL11A-13456 − UUGGAAUGUAGAGAGGCA 18 5′ 15799 BCL11A-13457 − UUUGGAAUGUAGAGAGGCA 19 5′ 15800 BCL11A-13458 − UUUUGGAAUGUAGAGAGGCA 20 5′ 15801 BCL11A-13459 − GUUUUGGAAUGUAGAGAGGCA 21 5′ 15802 BCL11A-13460 − UGUUUUGGAAUGUAGAGAGGCA 22 5′ 15803 BCL11A-13461 − CUGUUUUGGAAUGUAGAGAGGCA 23 5′ 15804 BCL11A-13462 − GCUGUUUUGGAAUGUAGAGAGGCA 24 5′ 15805 BCL11A-13463 − CAACACAAGUUGUGUAGA 18 5′ 15806 BCL11A-13464 − GCAACACAAGUUGUGUAGA 19 5′ 15807 BCL11A-13465 − UGCAACACAAGUUGUGUAGA 20 5′ 15808 BCL11A-13466 − GUGCAACACAAGUUGUGUAGA 21 5′ 15809 BCL11A-13467 − AGUGCAACACAAGUUGUGUAGA 22 5′ 15810 BCL11A-13468 − UAGUGCAACACAAGUUGUGUAGA 23 5′ 15811 BCL11A-13469 − CUAGUGCAACACAAGUUGUGUAGA 24 5′ 15812 BCL11A-13470 − AGGCUGUUUUGGAAUGUA 18 5′ 15813 BCL11A-13471 − AAGGCUGUUUUGGAAUGUA 19 5′ 15814 BCL11A-13472 − AAAGGCUGUUUUGGAAUGUA 20 5′ 15815 BCL11A-13473 − AAAAGGCUGUUUUGGAAUGUA 21 5′ 15816 BCL11A-13474 − UAAAAGGCUGUUUUGGAAUGUA 22 5′ 15817 BCL11A-13475 − AUAAAAGGCUGUUUUGGAAUGUA 23 5′ 15818 BCL11A-13476 − AAUAAAAGGCUGUUUUGGAAUGUA 24 5′ 15819 BCL11A-13477 − UGGAAUGUAGAGAGGCAG 18 5′ 15820 BCL11A-13478 − UUGGAAUGUAGAGAGGCAG 19 5′ 15821 BCL11A-13479 − UUUGGAAUGUAGAGAGGCAG 20 5′ 15822 BCL11A-13480 − UUUUGGAAUGUAGAGAGGCAG 21 5′ 15823 BCL11A-13481 − GUUUUGGAAUGUAGAGAGGCAG 22 5′ 15824 BCL11A-13482 − UGUUUUGGAAUGUAGAGAGGCAG 23 5′ 15825 BCL11A-13483 − CUGUUUUGGAAUGUAGAGAGGCAG 24 5′ 15826 BCL11A-13484 − CUUAAAUUUUUAUGUGAG 18 5′ 15827 BCL11A-13485 − UCUUAAAUUUUUAUGUGAG 19 5′ 15828 BCL11A-13486 − GUCUUAAAUUUUUAUGUGAG 20 5′ 15829 BCL11A-13487 − CGUCUUAAAUUUUUAUGUGAG 21 5′ 15830 BCL11A-13488 − CCGUCUUAAAUUUUUAUGUGAG 22 5′ 15831 BCL11A-13489 − CCCGUCUUAAAUUUUUAUGUGAG 23 5′ 15832 BCL11A-13490 − UCCCGUCUUAAAUUUUUAUGUGAG 24 5′ 15833 BCL11A-13491 − UAAGAAAGCAGUGUAAGG 18 5′ 15834 BCL11A-13492 − UUAAGAAAGCAGUGUAAGG 19 5′ 15835 BCL11A-13493 − AUUAAGAAAGCAGUGUAAGG 20 5′ 15836 BCL11A-13494 − AAUUAAGAAAGCAGUGUAAGG 21 5′ 15837 BCL11A-13495 − UAAUUAAGAAAGCAGUGUAAGG 22 5′ 15838 BCL11A-13496 − GUAAUUAAGAAAGCAGUGUAAGG 23 5′ 15839 BCL11A-13497 − UGUAAUUAAGAAAGCAGUGUAAGG 24 5′ 15840 BCL11A-13498 − UUUUGGAAUGUAGAGAGG 18 5′ 15841 BCL11A-13499 − GUUUUGGAAUGUAGAGAGG 19 5′ 15842 BCL11A-13500 − UGUUUUGGAAUGUAGAGAGG 20 5′ 15843 BCL11A-13501 − CUGUUUUGGAAUGUAGAGAGG 21 5′ 15844 BCL11A-13502 − GCUGUUUUGGAAUGUAGAGAGG 22 5′ 15845 BCL11A-13503 − GGCUGUUUUGGAAUGUAGAGAGG 23 5′ 15846 BCL11A-13504 − AGGCUGUUUUGGAAUGUAGAGAGG 24 5′ 15847 BCL11A-13505 − AAAGGCUGUUUUGGAAUG 18 5′ 15848 BCL11A-13506 − AAAAGGCUGUUUUGGAAUG 19 5′ 15849 BCL11A-13507 − UAAAAGGCUGUUUUGGAAUG 20 5′ 15850 BCL11A-13508 − AUAAAAGGCUGUUUUGGAAUG 21 5′ 15851 BCL11A-13509 − AAUAAAAGGCUGUUUUGGAAUG 22 5′ 15852 BCL11A-13510 − GAAUAAAAGGCUGUUUUGGAAUG 23 5′ 15853 BCL11A-13511 − AGAAUAAAAGGCUGUUUUGGAAUG 24 5′ 15854 BCL11A-13512 − AGUGCAACACAAGUUGUG 18 5′ 15855 BCL11A-13513 − UAGUGCAACACAAGUUGUG 19 5′ 15856 BCL11A-13514 − CUAGUGCAACACAAGUUGUG 20 5′ 15857 BCL11A-13515 − CCUAGUGCAACACAAGUUGUG 21 5′ 15858 BCL11A-13516 − ACCUAGUGCAACACAAGUUGUG 22 5′ 15859 BCL11A-13517 − CACCUAGUGCAACACAAGUUGUG 23 5′ 15860 BCL11A-13518 − UCACCUAGUGCAACACAAGUUGUG 24 5′ 15861 BCL11A-13519 − CCCGUCUUAAAUUUUUAU 18 5′ 15862 BCL11A-13520 − UCCCGUCUUAAAUUUUUAU 19 5′ 15863 BCL11A-13521 − UUCCCGUCUUAAAUUUUUAU 20 5′ 15864 BCL11A-13522 − UUUCCCGUCUUAAAUUUUUAU 21 5′ 15865 BCL11A-13523 − UUUUCCCGUCUUAAAUUUUUAU 22 5′ 15866 BCL11A-13524 − GUUUUCCCGUCUUAAAUUUUUAU 23 5′ 15867 BCL11A-13525 − UGUUUUCCCGUCUUAAAUUUUUAU 24 5′ 15868 BCL11A-13526 − GAGCACACUGCUGUAAUU 18 5′ 15869 BCL11A-13527 − UGAGCACACUGCUGUAAUU 19 5′ 15870 BCL11A-13528 − AUGAGCACACUGCUGUAAUU 20 5′ 15871 BCL11A-13529 − GAUGAGCACACUGCUGUAAUU 21 5′ 15872 BCL11A-13530 − AGAUGAGCACACUGCUGUAAUU 22 5′ 15873 BCL11A-13531 − GAGAUGAGCACACUGCUGUAAUU 23 5′ 15874 BCL11A-13532 − UGAGAUGAGCACACUGCUGUAAUU 24 5′ 15875 BCL11A-13533 − UUAGAAUAAAAGGCUGUU 18 5′ 15876 BCL11A-13534 − AUUAGAAUAAAAGGCUGUU 19 5′ 15877 BCL11A-13535 − AAUUAGAAUAAAAGGCUGUU 20 5′ 15878 BCL11A-13536 − UAAUUAGAAUAAAAGGCUGUU 21 5′ 15879 BCL11A-13537 − AUAAUUAGAAUAAAAGGCUGUU 22 5′ 15880 BCL11A-13538 − AAUAAUUAGAAUAAAAGGCUGUU 23 5′ 15881 BCL11A-13539 − AAAUAAUUAGAAUAAAAGGCUGUU 24 5′ 15882 BCL11A-13540 + UUUCAUUUUUUGCUGACA 18 3′ 15883 BCL11A-13541 + GUUUCAUUUUUUGCUGACA 19 3′ 15884 BCL11A-13542 + UGUUUCAUUUUUUGCUGACA 20 3′ 15885 BCL11A-13543 + UUGUUUCAUUUUUUGCUGACA 21 3′ 15886 BCL11A-13544 + UUUGUUUCAUUUUUUGCUGACA 22 3′ 15887 BCL11A-13545 + UUUUGUUUCAUUUUUUGCUGACA 23 3′ 15888 BCL11A-13546 + UUUUUGUUUCAUUUUUUGCUGACA 24 3′ 15889 BCL11A-13547 + AAUAGUUUGCUUCCCCCA 18 3′ 15890 BCL11A-13548 + AAAUAGUUUGCUUCCCCCA 19 3′ 15891 BCL11A-13549 + UAAAUAGUUUGCUUCCCCCA 20 3′ 15892 BCL11A-13550 + GUAAAUAGUUUGCUUCCCCCA 21 3′ 15893 BCL11A-13551 + UGUAAAUAGUUUGCUUCCCCCA 22 3′ 15894 BCL11A-13552 + CUGUAAAUAGUUUGCUUCCCCCA 23 3′ 15895 BCL11A-13553 + GCUGUAAAUAGUUUGCUUCCCCCA 24 3′ 15896 BCL11A-13554 + AAUACUUACUGUACUGCA 18 3′ 15897 BCL11A-13555 + AAAUACUUACUGUACUGCA 19 3′ 15898 BCL11A-13556 + AAAAUACUUACUGUACUGCA 20 3′ 15899 BCL11A-13557 + GAAAAUACUUACUGUACUGCA 21 3′ 15900 BCL11A-13558 + AGAAAAUACUUACUGUACUGCA 22 3′ 15901 BCL11A-13559 + AAGAAAAUACUUACUGUACUGCA 23 3′ 15902 BCL11A-13560 + AAAGAAAAUACUUACUGUACUGCA 24 3′ 15903 BCL11A-13561 + UGCUACUUAUACAAUUCA 18 3′ 15904 BCL11A-13562 + GUGCUACUUAUACAAUUCA 19 3′ 15905 BCL11A-13563 + AGUGCUACUUAUACAAUUCA 20 3′ 15906 BCL11A-13564 + CAGUGCUACUUAUACAAUUCA 21 3′ 15907 BCL11A-13565 + UCAGUGCUACUUAUACAAUUCA 22 3′ 15908 BCL11A-13566 + CUCAGUGCUACUUAUACAAUUCA 23 3′ 15909 BCL11A-13567 + ACUCAGUGCUACUUAUACAAUUCA 24 3′ 15910 BCL11A-13568 + GUUUGCUUCCCCCAAUGA 18 3′ 15911 BCL11A-13569 + AGUUUGCUUCCCCCAAUGA 19 3′ 15912 BCL11A-13570 + UAGUUUGCUUCCCCCAAUGA 20 3′ 15913 BCL11A-13571 + AUAGUUUGCUUCCCCCAAUGA 21 3′ 15914 BCL11A-13572 + AAUAGUUUGCUUCCCCCAAUGA 22 3′ 15915 BCL11A-13573 + AAAUAGUUUGCUUCCCCCAAUGA 23 3′ 15916 BCL11A-13574 + UAAAUAGUUUGCUUCCCCCAAUGA 24 3′ 15917 BCL11A-13575 + UUUCUAGUUUUGCUUAAC 18 3′ 15918 BCL11A-13576 + CUUUCUAGUUUUGCUUAAC 19 3′ 15919 BCL11A-13577 + ACUUUCUAGUUUUGCUUAAC 20 3′ 15920 BCL11A-13578 + AACUUUCUAGUUUUGCUUAAC 21 3′ 15921 BCL11A-13579 + AAACUUUCUAGUUUUGCUUAAC 22 3′ 15922 BCL11A-13580 + AAAACUUUCUAGUUUUGCUUAAC 23 3′ 15923 BCL11A-13581 + UAAAACUUUCUAGUUUUGCUUAAC 24 3′ 15924 BCL11A-13582 + GCUACUUAUACAAUUCAC 18 3′ 15925 BCL11A-13583 + UGCUACUUAUACAAUUCAC 19 3′ 15926 BCL11A-13584 + GUGCUACUUAUACAAUUCAC 20 3′ 15927 BCL11A-13585 + AGUGCUACUUAUACAAUUCAC 21 3′ 15928 BCL11A-13586 + CAGUGCUACUUAUACAAUUCAC 22 3′ 15929 BCL11A-13587 + UCAGUGCUACUUAUACAAUUCAC 23 3′ 15930 BCL11A-13588 + CUCAGUGCUACUUAUACAAUUCAC 24 3′ 15931 BCL11A-13589 + AAAUACUUACUGUACUGC 18 3′ 15932 BCL11A-13590 + AAAAUACUUACUGUACUGC 19 3′ 15933 BCL11A-13591 + GAAAAUACUUACUGUACUGC 20 3′ 15934 BCL11A-13592 + AGAAAAUACUUACUGUACUGC 21 3′ 15935 BCL11A-13593 + AAGAAAAUACUUACUGUACUGC 22 3′ 15936 BCL11A-13594 + AAAGAAAAUACUUACUGUACUGC 23 3′ 15937 BCL11A-13595 + GAAAGAAAAUACUUACUGUACUGC 24 3′ 15938 BCL11A-13596 + AAAAUACUUACUGUACUG 18 3′ 15939 BCL11A-13597 + GAAAAUACUUACUGUACUG 19 3′ 15940 BCL11A-13598 + AGAAAAUACUUACUGUACUG 20 3′ 15941 BCL11A-13599 + AAGAAAAUACUUACUGUACUG 21 3′ 15942 BCL11A-13600 + AAAGAAAAUACUUACUGUACUG 22 3′ 15943 BCL11A-13601 + GAAAGAAAAUACUUACUGUACUG 23 3′ 15944 BCL11A-13602 + UGAAAGAAAAUACUUACUGUACUG 24 3′ 15945 BCL11A-13603 − GUUCUGUGUCAGCAAAAA 18 3′ 15946 BCL11A-13604 − AGUUCUGUGUCAGCAAAAA 19 3′ 15947 BCL11A-13605 − GAGUUCUGUGUCAGCAAAAA 20 3′ 15948 BCL11A-13606 − UGAGUUCUGUGUCAGCAAAAA 21 3′ 15949 BCL11A-13607 − CUGAGUUCUGUGUCAGCAAAAA 22 3′ 15950 BCL11A-13608 − ACUGAGUUCUGUGUCAGCAAAAA 23 3′ 15951 BCL11A-13609 − CACUGAGUUCUGUGUCAGCAAAAA 24 3′ 15952 BCL11A-13610 − AGUAAGUAUUUUCUUUCA 18 3′ 15953 BCL11A-13611 − CAGUAAGUAUUUUCUUUCA 19 3′ 15954 BCL11A-13612 − ACAGUAAGUAUUUUCUUUCA 20 3′ 15955 BCL11A-13613 − UACAGUAAGUAUUUUCUUUCA 21 3′ 15956 BCL11A-13614 − GUACAGUAAGUAUUUUCUUUCA 22 3′ 15957 BCL11A-13615 − AGUACAGUAAGUAUUUUCUUUCA 23 3′ 15958 BCL11A-13616 − CAGUACAGUAAGUAUUUUCUUUCA 24 3′ 15959 BCL11A-13617 − UUUCAUGUUAAGCAAAAC 18 3′ 15960 BCL11A-13618 − UUUUCAUGUUAAGCAAAAC 19 3′ 15961 BCL11A-13619 − AUUUUCAUGUUAAGCAAAAC 20 3′ 15962 BCL11A-13620 − UAUUUUCAUGUUAAGCAAAAC 21 3′ 15963 BCL11A-13621 − UUAUUUUCAUGUUAAGCAAAAC 22 3′ 15964 BCL11A-13622 − AUUAUUUUCAUGUUAAGCAAAAC 23 3′ 15965 BCL11A-13623 − UAUUAUUUUCAUGUUAAGCAAAAC 24 3′ 15966 BCL11A-13624 − AGUAUUUUCUUUCAUUGG 18 3′ 15967 BCL11A-13625 − AAGUAUUUUCUUUCAUUGG 19 3′ 15968 BCL11A-13626 − UAAGUAUUUUCUUUCAUUGG 20 3′ 15969 BCL11A-13627 − GUAAGUAUUUUCUUUCAUUGG 21 3′ 15970 BCL11A-13628 − AGUAAGUAUUUUCUUUCAUUGG 22 3′ 15971 BCL11A-13629 − CAGUAAGUAUUUUCUUUCAUUGG 23 3′ 15972 BCL11A-13630 − ACAGUAAGUAUUUUCUUUCAUUGG 24 3′ 15973 BCL11A-13631 − AAGUAUUUUCUUUCAUUG 18 3′ 15974 BCL11A-13632 − UAAGUAUUUUCUUUCAUUG 19 3′ 15975 BCL11A-13633 − GUAAGUAUUUUCUUUCAUUG 20 3′ 15976 BCL11A-13634 − AGUAAGUAUUUUCUUUCAUUG 21 3′ 15977 BCL11A-13635 − CAGUAAGUAUUUUCUUUCAUUG 22 3′ 15978 BCL11A-13636 − ACAGUAAGUAUUUUCUUUCAUUG 23 3′ 15979 BCL11A-13637 − UACAGUAAGUAUUUUCUUUCAUUG 24 3′ 15980 BCL11A-13638 − GUAAGUAUUUUCUUUCAU 18 3′ 15981 BCL11A-13639 − AGUAAGUAUUUUCUUUCAU 19 3′ 15982 BCL11A-13640 − CAGUAAGUAUUUUCUUUCAU 20 3′ 15983 BCL11A-13641 − ACAGUAAGUAUUUUCUUUCAU 21 3′ 15984 BCL11A-13642 − UACAGUAAGUAUUUUCUUUCAU 22 3′ 15985 BCL11A-13643 − GUACAGUAAGUAUUUUCUUUCAU 23 3′ 15986 BCL11A-13644 − AGUACAGUAAGUAUUUUCUUUCAU 24 3′ 15987 BCL11A-13645 − UUGGCUAUUGAUACUGAU 18 3′ 15988 BCL11A-13646 − UUUGGCUAUUGAUACUGAU 19 3′ 15989 BCL11A-13647 − CUUUGGCUAUUGAUACUGAU 20 3′ 15990 BCL11A-13648 − UCUUUGGCUAUUGAUACUGAU 21 3′ 15991 BCL11A-13649 − AUCUUUGGCUAUUGAUACUGAU 22 3′ 15992 BCL11A-13650 − GAUCUUUGGCUAUUGAUACUGAU 23 3′ 15993 BCL11A-13651 − GGAUCUUUGGCUAUUGAUACUGAU 24 3′ 15994 BCL11A-13652 − UAAGUAUUUUCUUUCAUU 18 3′ 15995 BCL11A-13653 − GUAAGUAUUUUCUUUCAUU 19 3′ 15996 BCL11A-13654 − AGUAAGUAUUUUCUUUCAUU 20 3′ 15997 BCL11A-13655 − CAGUAAGUAUUUUCUUUCAUU 21 3′ 15998 BCL11A-13656 − ACAGUAAGUAUUUUCUUUCAUU 22 3′ 15999 BCL11A-13657 − UACAGUAAGUAUUUUCUUUCAUU 23 3′ 16000 BCL11A-13658 − GUACAGUAAGUAUUUUCUUUCAUU 24 3′ 16001

Table 23A provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the first tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS), have a high level of orthogonality, and start with 5′G. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 23A 1st Tier Target SEQ DNA Site 5′ ID gRNA Name Strand Targeting Domain Length or 3′ NO: BCL11A-13659 − GGAUCUUUGGCUAUUGA 17 3′ 16002

Table 23B provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the second tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS) and have a high level of orthogonality. It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 23B 2nd Tier Target SEQ DNA Site 5′ ID gRNA Name Strand Targeting Domain Length or 3′ NO: BCL11A-13660 + UCGGUAAAACUUUCUAG 17 3′ 16003 BCL11A-13661 − UUUGGAUCUUUGGCUAUUGA 20 3′ 16004 BCL11A-13662 + CCCUGUUAUGGCUGUAAAUA 20 3′ 16005 BCL11A-13663 + AAUUCGGUAAAACUUUCUAG 20 3′ 16006

Table 23C provides exemplary targeting domains for removing (e.g., deleting) the enhancer region of the BCL11A gene selected according to the fourth tier parameters. The targeting domains bind within a region 5′ (51.5 to 51.7 kb downstream of TSS) or 3′ (65.1 to 65.3 kb downstream of TSS). It is contemplated herein that in an embodiment the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis Cas9 molecule that generates a double stranded break (Cas9 nuclease) or a single-stranded break (Cas9 nickase).

TABLE 23C 4th Tier Target SEQ DNA Site 5′ ID gRNA Name Strand Targeting Domain Length or 3′ NO: BCL11A-13664 + CACUGCGCCCAGCCUUA 17 5′ 16007 BCL11A-13665 + AGCCACUGCGCCCAGCCUUA 20 5′ 16008 BCL11A-13666 + UGUUAUGGCUGUAAAUA 17 3′ 16009

Table 24A provides exemplary targeting domains for correcting a mutation (e.g., E6V) in the HBB gene selected according to the first tier parameters. The targeting domains bind within 200 bp to a mutation (e.g., E6V) and have a high level of orthogonality. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

TABLE 24A 1st Tier Target SEQ gRNA DNA Site ID Name Strand Targeting Domain Length NO: HBB-19 + GUUCACCUUGCCCCACA 17 16010 HBB-5 + AGGAGUCAGGUGCACCA 17 16011 HBB-40 − UACUGCCCUGUGGGGCA 17 16012 HBB-70 − GCUGGGCAUAAAAGUCA 17 16013 HBB-71 − GUUACAAGACAGGUUUA 17 16014 HBB-72 − AGGAGACCAAUAGAAAC 17 16015 HBB-37 + CGUUCACCUUGCCCCAC 17 16016 HBB-3 + ACGGCAGACUUCUCCAC 17 16017 HBB-41 − UAUCAAGGUUACAAGAC 17 16018 HBB-73 + ACUUUUAUGCCCAGCCC 17 16019 HBB-74 − GGCUGGGCAUAAAAGUC 17 16020 HBB-4 + ACUUCUCCACAGGAGUC 17 16021 HBB-75 − AAUAGAAACUGGGCAUG 17 16022 HBB-38 − CUGCCGUUACUGCCCUG 17 16023 HBB-13 − GGAUGAAGUUGGUGGUG 17 16024 HBB-12 − GCCGUUACUGCCCUGUG 17 16025 HBB-76 + ACAUGCCCAGUUUCUAU 17 16026 HBB-77 − GGAGACCAAUAGAAACU 17 16027 HBB-15 − GUGAACGUGGAUGAAGU 17 16028 HBB-47 − UGCCGUUACUGCCCUGU 17 16029 HBB-39 + CUUGCCCCACAGGGCAGUAA 20 16030 HBB-30 + CACGUUCACCUUGCCCCACA 20 16031 HBB-7 + CACAGGAGUCAGGUGCACCA 20 16032 HBB-78 − AGCAGGGAGGGCAGGAGCCA 20 16033 HBB-36 − CGUUACUGCCCUGUGGGGCA 20 16034 HBB-79 − AGGGCUGGGCAUAAAAGUCA 20 16035 HBB-22 + AAGCAAAUGUAAGCAAUAGA 20 16036 HBB-80 − AAGGUUACAAGACAGGUUUA 20 16037 HBB-81 − UUAAGGAGACCAAUAGAAAC 20 16038 HBB-2 + GUAACGGCAGACUUCUCCAC 20 16039 HBB-49 − UGGUAUCAAGGUUACAAGAC 20 16040 HBB-82 + CUGACUUUUAUGCCCAGCCC 20 16041 HBB-43 − UGAAGUUGGUGGUGAGGCCC 20 16042 HBB-83 − GAGCAGGGAGGGCAGGAGCC 20 16043 HBB-84 − CAGGGCUGGGCAUAAAAGUC 20 16044 HBB-8 + CAGACUUCUCCACAGGAGUC 20 16045 HBB-16 − GUGAACGUGGAUGAAGUUGG 20 16046 HBB-85 − ACCAAUAGAAACUGGGCAUG 20 16047 HBB-27 − AGUCUGCCGUUACUGCCCUG 20 16048 HBB-35 − CGUGGAUGAAGUUGGUGGUG 20 16049 HBB-42 − UCUGCCGUUACUGCCCUGUG 20 16050 HBB-86 − UAAGGAGACCAAUAGAAACU 20 16051 HBB-9 − GAAGUUGGUGGUGAGGCCCU 20 16052 HBB-87 − GGAGGGCAGGAGCCAGGGCU 20 16053 HBB-23 − AAGGUGAACGUGGAUGAAGU 20 16054 HBB-14 − GUCUGCCGUUACUGCCCUGU 20 16055

Table 24B provides exemplary targeting domains for correcting a mutation (e.g., E6V) in the HBB gene selected according to the second tier parameters. The targeting domains bind within 200 bp to a mutation (e.g., E6V) and start with a 5′G. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

TABLE 24B 2nd Tier Target SEQ gRNA DNA Site ID Name Strand Targeting Domain Length NO: HBB-11 + GCCCCACAGGGCAGUAA 17 16056 HBB-18 − GUGGUGAGGCCCUGGGC 17 16057 HBB-17 − GUGGGGCAAGGUGAACG 17 16058 HBB-1 − GGUGCACCUGACUCCUG 17 16059 HBB-20 − GUUGGUGGUGAGGCCCU 17 16060 HBB-88 − GGGCAGGAGCCAGGGCU 17 16061 HBB-10 − GCAACCUCAAACAGACACCA 20 16062 HBB-89 − GGGAGGGCAGGAGCCAGGGC 20 16063

Table 24C provides exemplary targeting domains for correcting a mutation (e.g., E6V) in the HBB gene selected according to the third tier parameters. The targeting domains bind within 200 bp to a mutation (e.g., E6V). It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

TABLE 24C 3rd Tier Target SEQ gRNA DNA Site ID Name Strand Targeting Domain Length NO: HBB-25 − ACCUCAAACAGACACCA 17 16064 HBB-45 + UGAUACCAACCUGCCCA 17 16065 HBB-90 − AGGGAGGGCAGGAGCCA 17 16066 HBB-48 − UGGGCAGGUUGGUAUCA 17 16067 HBB-29 + CAAAUGUAAGCAAUAGA 17 16068 HBB-28 − AGUUGGUGGUGAGGCCC 17 16069 HBB-51 + UUGAUACCAACCUGCCC 17 16070 HBB-91 − CAGGGAGGGCAGGAGCC 17 16071 HBB-92 − AGGGCAGGAGCCAGGGC 17 16072 HBB-21 − AACGUGGAUGAAGUUGG 17 16073 HBB-24 + ACCAUGGUGUCUGUUUG 17 16074 HBB-44 − UGAGGCCCUGGGCAGGU 17 16075 HBB-34 + CCUUGAUACCAACCUGCCCA 20 16076 HBB-32 − CCCUGGGCAGGUUGGUAUCA 20 16077 HBB-31 + CCACGUUCACCUUGCCCCAC 20 16078 HBB-26 + ACCUUGAUACCAACCUGCCC 20 16079 HBB-52 − UUGGUGGUGAGGCCCUGGGC 20 16080 HBB-33 − CCUGUGGGGCAAGGUGAACG 20 16081 HBB-6 − CAUGGUGCACCUGACUCCUG 20 16082 HBB-46 + UGCACCAUGGUGUCUGUUUG 20 16083 HBB-50 − UGGUGAGGCCCUGGGCAGGU 20 16084

Table 24D provides targeting domains for correcting a mutation (e.g., E6V) in the HBB gene by dual targeting (e.g., dual single strand cleavages). In an embodiment, dual targeting (e.g., dual nicking) is used to create two nicks on opposite DNA strands by using S. pyogenes Cas9 nickases with two targeting domains that are complementary to opposite DNA strands, e.g., a gRNA comprising any minus strand targeting domain may be paired any gRNA comprising a plus strand targeting domain provided that the two gRNAs are oriented on the DNA such that PAMs face outward and the distance between the 5′ ends of the gRNAs is 0-50 bp. Exemplary nickase pairs include a targeting domain from Group A and a second targeting domain from Group B in Table 24D (for S. pyogenes). It is contemplated herein that in an embodiment a targeting domain of Group A can be combined with any of the targeting domains of Group B in Table 24D (for S. pyogenes). For example, HBB-9 or HBB-20 can be combined with HBB-11 or HBB-39.

TABLE 24D Group A Group B HBB-9, HBB-20 HBB-11, HBB-39

Table 25A provides exemplary targeting domains for correcting a mutation (e.g., E6V) in the HBB gene selected according to the first tier parameters. The targeting domains bind within 200 bp to a mutation (e.g., E6V), and have a high level of orthogonality. The PAM is NNGRRT. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

TABLE 25A 1st Tier Target SEQ gRNA DNA Site ID Name Strand Targeting Domain Length NO: HBB-93 + AACGGCAGACUUCUCCAC 18 16085 HBB-94 + UAACGGCAGACUUCUCCAC 19 16086 HBB-2 + GUAACGGCAGACUUCUCCAC 20 16087 HBB-95 + AGUAACGGCAGACUUCUCCAC 21 16088 HBB-96 + CAGUAACGGCAGACUUCUCCAC 22 16089 HBB-97 + GCAGUAACGGCAGACUUCUCCAC 23 16090 HBB-98 + GGCAGUAACGGCAGACUUCUCCAC 24 16091 HBB-99 − CUGUGGGGCAAGGUGAAC 18 16092 HBB-100 − CCUGUGGGGCAAGGUGAAC 19 16093 HBB-101 − CCCUGUGGGGCAAGGUGAAC 20 16094 HBB-102 − GCCCUGUGGGGCAAGGUGAAC 21 16095 HBB-103 − UGCCCUGUGGGGCAAGGUGAAC 22 16096 HBB-104 − CUGCCCUGUGGGGCAAGGUGAAC 23 16097 HBB-105 − ACUGCCCUGUGGGGCAAGGUGAAC 24 16098

Table 25B provides exemplary targeting domains for correcting a mutation (e.g., E6V) in the HBB gene selected according to the fourth tier parameters. The targeting domains bind within 200 bp to a mutation (e.g., E6V), and the PAM is NNGRRV. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a S. pyogenes Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

TABLE 25B 4th Tier Target SEQ gRNA DNA Site ID Name Strand Targeting Domain Length NO: HBB-106 + CACGUUCACCUUGCCCCA 18 16099 HBB-107 + CCACGUUCACCUUGCCCCA 19 16100 HBB-58 + UCCACGUUCACCUUGCCCCA 20 16101 HBB-108 + AUCCACGUUCACCUUGCCCCA 21 16102 HBB-109 + CAUCCACGUUCACCUUGCCCCA 22 16103 HBB-110 + UCAUCCACGUUCACCUUGCCCCA 23 16104 HBB-111 + UUCAUCCACGUUCACCUUGCCCCA 24 16105 HBB-112 + UAACGGCAGACUUCUCCA 18 16106 HBB-113 + GUAACGGCAGACUUCUCCA 19 16107 HBB-69 + AGUAACGGCAGACUUCUCCA 20 16108 HBB-114 + CAGUAACGGCAGACUUCUCCA 21 16109 HBB-115 + GCAGUAACGGCAGACUUCUCCA 22 16110 HBB-116 + GGCAGUAACGGCAGACUUCUCCA 23 16111 HBB-117 + GGGCAGUAACGGCAGACUUCUCCA 24 16112 HBB-118 + GUCUGUUUGAGGUUGCUA 18 16113 HBB-119 + UGUCUGUUUGAGGUUGCUA 19 16114 HBB-66 + GUGUCUGUUUGAGGUUGCUA 20 16115 HBB-120 + GGUGUCUGUUUGAGGUUGCUA 21 16116 HBB-121 + UGGUGUCUGUUUGAGGUUGCUA 22 16117 HBB-122 + AUGGUGUCUGUUUGAGGUUGCUA 23 16118 HBB-123 + CAUGGUGUCUGUUUGAGGUUGCUA 24 16119 HBB-124 + CCUUGAUACCAACCUGCC 18 16120 HBB-125 + ACCUUGAUACCAACCUGCC 19 16121 HBB-57 + AACCUUGAUACCAACCUGCC 20 16122 HBB-126 + UAACCUUGAUACCAACCUGCC 21 16123 HBB-127 + GUAACCUUGAUACCAACCUGCC 22 16124 HBB-128 + UGUAACCUUGAUACCAACCUGCC 23 16125 HBB-129 + UUGUAACCUUGAUACCAACCUGCC 24 16126 HBB-130 + GUGCACCAUGGUGUCUGU 18 16127 HBB-131 + GGUGCACCAUGGUGUCUGU 19 16128 HBB-62 + AGGUGCACCAUGGUGUCUGU 20 16129 HBB-132 + CAGGUGCACCAUGGUGUCUGU 21 16130 HBB-133 + UCAGGUGCACCAUGGUGUCUGU 22 16131 HBB-134 + GUCAGGUGCACCAUGGUGUCUGU 23 16132 HBB-135 + AGUCAGGUGCACCAUGGUGUCUGU 24 16133 HBB-136 + UAGUGAACACAGUUGUGU 18 16134 HBB-137 + CUAGUGAACACAGUUGUGU 19 16135 HBB-59 + GCUAGUGAACACAGUUGUGU 20 16136 HBB-138 + UGCUAGUGAACACAGUUGUGU 21 16137 HBB-139 + UUGCUAGUGAACACAGUUGUGU 22 16138 HBB-140 + GUUGCUAGUGAACACAGUUGUGU 23 16139 HBB-141 + GGUUGCUAGUGAACACAGUUGUGU 24 16140 HBB-142 − UAAGGAGACCAAUAGAAA 18 16141 HBB-143 − UUAAGGAGACCAAUAGAAA 19 16142 HBB-144 − UUUAAGGAGACCAAUAGAAA 20 16143 HBB-145 − GUUUAAGGAGACCAAUAGAAA 21 16144 HBB-146 − GGUUUAAGGAGACCAAUAGAAA 22 16145 HBB-147 − AGGUUUAAGGAGACCAAUAGAAA 23 16146 HBB-148 − CAGGUUUAAGGAGACCAAUAGAAA 24 16147 HBB-149 − CAGGUUUAAGGAGACCAA 18 16148 HBB-150 − ACAGGUUUAAGGAGACCAA 19 16149 HBB-151 − GACAGGUUUAAGGAGACCAA 20 16150 HBB-152 − AGACAGGUUUAAGGAGACCAA 21 16151 HBB-153 − AAGACAGGUUUAAGGAGACCAA 22 16152 HBB-154 − CAAGACAGGUUUAAGGAGACCAA 23 16153 HBB-155 − ACAAGACAGGUUUAAGGAGACCAA 24 16154 HBB-156 − GGUUACAAGACAGGUUUA 18 16155 HBB-157 − AGGUUACAAGACAGGUUUA 19 16156 HBB-80 − AAGGUUACAAGACAGGUUUA 20 16157 HBB-158 − CAAGGUUACAAGACAGGUUUA 21 16158 HBB-159 − UCAAGGUUACAAGACAGGUUUA 22 16159 HBB-160 − AUCAAGGUUACAAGACAGGUUUA 23 16160 HBB-161 − UAUCAAGGUUACAAGACAGGUUUA 24 16161 HBB-162 − GAAGUUGGUGGUGAGGCC 18 16162 HBB-163 − UGAAGUUGGUGGUGAGGCC 19 16163 HBB-68 − AUGAAGUUGGUGGUGAGGCC 20 16164 HBB-164 − GAUGAAGUUGGUGGUGAGGCC 21 16165 HBB-165 − GGAUGAAGUUGGUGGUGAGGCC 22 16166 HBB-166 − UGGAUGAAGUUGGUGGUGAGGCC 23 16167 HBB-167 − GUGGAUGAAGUUGGUGGUGAGGCC 24 16168 HBB-168 − ACUGCCCUGUGGGGCAAG 18 16169 HBB-169 − UACUGCCCUGUGGGGCAAG 19 16170 HBB-65 − UUACUGCCCUGUGGGGCAAG 20 16171 HBB-170 − GUUACUGCCCUGUGGGGCAAG 21 16172 HBB-171 − CGUUACUGCCCUGUGGGGCAAG 22 16173 HBB-172 − CCGUUACUGCCCUGUGGGGCAAG 23 16174 HBB-173 − GCCGUUACUGCCCUGUGGGGCAAG 24 16175 HBB-174 − GGAGGGCAGGAGCCAGGG 18 16176 HBB-175 − GGGAGGGCAGGAGCCAGGG 19 16177 HBB-176 − AGGGAGGGCAGGAGCCAGGG 20 16178 HBB-177 − CAGGGAGGGCAGGAGCCAGGG 21 16179 HBB-178 − GCAGGGAGGGCAGGAGCCAGGG 22 16180 HBB-179 − AGCAGGGAGGGCAGGAGCCAGGG 23 16181 HBB-180 − GAGCAGGGAGGGCAGGAGCCAGGG 24 16182 HBB-181 − UGGGCAUAAAAGUCAGGG 18 16183 HBB-182 − CUGGGCAUAAAAGUCAGGG 19 16184 HBB-183 − GCUGGGCAUAAAAGUCAGGG 20 16185 HBB-184 − GGCUGGGCAUAAAAGUCAGGG 21 16186 HBB-185 − GGGCUGGGCAUAAAAGUCAGGG 22 16187 HBB-186 − AGGGCUGGGCAUAAAAGUCAGGG 23 16188 HBB-187 − CAGGGCUGGGCAUAAAAGUCAGGG 24 16189 HBB-188 − GGGGCAAGGUGAACGUGG 18 16190 HBB-189 − UGGGGCAAGGUGAACGUGG 19 16191 HBB-67 − GUGGGGCAAGGUGAACGUGG 20 16192 HBB-190 − UGUGGGGCAAGGUGAACGUGG 21 16193 HBB-191 − CUGUGGGGCAAGGUGAACGUGG 22 16194 HBB-192 − CCUGUGGGGCAAGGUGAACGUGG 23 16195 HBB-193 − CCCUGUGGGGCAAGGUGAACGUGG 24 16196 HBB-194 − UCUGCCGUUACUGCCCUG 18 16197 HBB-195 − GUCUGCCGUUACUGCCCUG 19 16198 HBB-27 − AGUCUGCCGUUACUGCCCUG 20 16199 HBB-196 − AAGUCUGCCGUUACUGCCCUG 21 16200 HBB-197 − GAAGUCUGCCGUUACUGCCCUG 22 16201 HBB-198 − AGAAGUCUGCCGUUACUGCCCUG 23 16202 HBB-199 − GAGAAGUCUGCCGUUACUGCCCUG 24 16203 HBB-200 − UGGUGCACCUGACUCCUG 18 16204 HBB-201 − AUGGUGCACCUGACUCCUG 19 16205 HBB-6 − CAUGGUGCACCUGACUCCUG 20 16206 HBB-202 − CCAUGGUGCACCUGACUCCUG 21 16207 HBB-203 − ACCAUGGUGCACCUGACUCCUG 22 16208 HBB-204 − CACCAUGGUGCACCUGACUCCUG 23 16209 HBB-205 − ACACCAUGGUGCACCUGACUCCUG 24 16210 HBB-206 − ACGUGGAUGAAGUUGGUG 18 16211 HBB-207 − AACGUGGAUGAAGUUGGUG 19 16212 HBB-64 − GAACGUGGAUGAAGUUGGUG 20 16213 HBB-208 − UGAACGUGGAUGAAGUUGGUG 21 16214 HBB-209 − GUGAACGUGGAUGAAGUUGGUG 22 16215 HBB-210 − GGUGAACGUGGAUGAAGUUGGUG 23 16216 HBB-211 − AGGUGAACGUGGAUGAAGUUGGUG 24 16217 HBB-212 − GUGCACCUGACUCCUGUG 18 16218 HBB-213 − GGUGCACCUGACUCCUGUG 19 16219 HBB-63 − UGGUGCACCUGACUCCUGUG 20 16220 HBB-214 − AUGGUGCACCUGACUCCUGUG 21 16221 HBB-215 − CAUGGUGCACCUGACUCCUGUG 22 16222 HBB-216 − CCAUGGUGCACCUGACUCCUGUG 23 16223 HBB-217 − ACCAUGGUGCACCUGACUCCUGUG 24 16224 HBB-218 − GUCUGCCGUUACUGCCCU 18 16225 HBB-219 − AGUCUGCCGUUACUGCCCU 19 16226 HBB-56 − AAGUCUGCCGUUACUGCCCU 20 16227 HBB-220 − GAAGUCUGCCGUUACUGCCCU 21 16228 HBB-221 − AGAAGUCUGCCGUUACUGCCCU 22 16229 HBB-222 − GAGAAGUCUGCCGUUACUGCCCU 23 16230 HBB-223 − GGAGAAGUCUGCCGUUACUGCCCU 24 16231 HBB-224 − AUGGUGCACCUGACUCCU 18 16232 HBB-225 − CAUGGUGCACCUGACUCCU 19 16233 HBB-60 − CCAUGGUGCACCUGACUCCU 20 16234 HBB-226 − ACCAUGGUGCACCUGACUCCU 21 16235 HBB-227 − CACCAUGGUGCACCUGACUCCU 22 16236 HBB-228 − ACACCAUGGUGCACCUGACUCCU 23 16237 HBB-229 − GACACCAUGGUGCACCUGACUCCU 24 16238 HBB-230 − AGGGCUGGGCAUAAAAGU 18 16239 HBB-231 − CAGGGCUGGGCAUAAAAGU 19 16240 HBB-232 − CCAGGGCUGGGCAUAAAAGU 20 16241 HBB-233 − GCCAGGGCUGGGCAUAAAAGU 21 16242 HBB-234 − AGCCAGGGCUGGGCAUAAAAGU 22 16243 HBB-235 − GAGCCAGGGCUGGGCAUAAAAGU 23 16244 HBB-236 − GGAGCCAGGGCUGGGCAUAAAAGU 24 16245 HBB-237 − AGGUUACAAGACAGGUUU 18 16246 HBB-238 − AAGGUUACAAGACAGGUUU 19 16247 HBB-239 − CAAGGUUACAAGACAGGUUU 20 16248 HBB-240 − UCAAGGUUACAAGACAGGUUU 21 16249 HBB-241 − AUCAAGGUUACAAGACAGGUUU 22 16250 HBB-242 − UAUCAAGGUUACAAGACAGGUUU 23 16251 HBB-243 − GUAUCAAGGUUACAAGACAGGUUU 24 16252

Table 26 provides exemplary targeting domains for correcting a mutation (e.g., E6V) in the HBB gene selected according to the first tier parameters. The targeting domains bind within 200 bp to a mutation (e.g., E6V) and have a high level of orthogonality. It is contemplated herein that the targeting domain hybridizes to the target domain through complementary base pairing. Any of the targeting domains in the table can be used with a N. meningitidis Cas9 molecule that generates a double strand break (Cas9 nuclease) or a single-strand break (Cas9 nickase).

TABLE 26 1st Tier Target SEQ gRNA DNA Site ID Name Strand Targeting Domain Length NO: HBB-244 − AGCCAUCUAUUGCUUAC 17 16253 HBB-245 − GUCAGGGCAGAGCCAUC 17 16254 HBB-246 − CAGAGCCAUCUAUUGCUUAC 20 16255 HBB-247 − AAAGUCAGGGCAGAGCCAUC 20 16256

III. Cas9 Molecules

Cas9 molecules of a variety of species can be used in the methods and compositions described herein. While the S. pyogenes, S. aureus, and S. thermophilus Cas9 molecules are the subject of much of the disclosure herein, Cas9 molecules of, derived from, or based on the Cas9 proteins of other species listed herein can be used as well. In other words, while the much of the description herein uses S. pyogenes and S. thermophilus Cas9 molecules, Cas9 molecules from the other species can replace them, e.g., Staphylococcus aureus and Neisseria meningitidis Cas9 molecules. Additional Cas9 species include: Acidovorax avenae, Actinobacillus pleuropneumoniae, Actinobacillus succinogenes, Actinobacillus suis, Actinomyces sp., Cycliphilus denitrificans, Aminomonas paucivorans, Bacillus cereus, Bacillus smithii, Bacillus thuringiensis, Bacteroides sp., Blastopirellula marina, Bradyrhizobium sp., Brevibacillus laterosporus, Campylobacter coli, Campylobacter jejuni, Campylobacter lari, Candidatus puniceispirillum, Clostridium cellulolyticum, Clostridium perfringens, Corynebacterium accolens, Corynebacterium diphtheria, Corynebacterium matruchotii, Dinoroseobacter shibae, Eubacterium dolichum, gamma proteobacterium, Gluconacetobacter diazotrophicus, Haemophilus parainfluenzae, Haemophilus sputorum, Helicobacter canadensis, Helicobacter cinaedi, Helicobacter mustelae, Ilyobacter polytropus, Kingella kingae, Lactobacillus crispatus, Listeria ivanovii, Listeria monocytogenes, Listeriaceae bacterium, Methylocystis sp., Methylosinus trichosporium, Mobiluncus mulieris, Neisseria bacilliformis, Neisseria cinerea, Neisseria flavescens, Neisseria lactamica, Neisseria sp., Neisseria wadsworthii, Nitrosomonas sp., Parvibaculum lavamentivorans, Pasteurella multocida, Phascolarctobacterium succinatutens, Ralstonia syzygii, Rhodopseudomonas palustris, Rhodovulum sp., Simonsiella muelleri, Sphingomonas sp., Sporolactobacillus vineae, Staphylococcus lugdunensis, Streptococcus sp., Subdoligranulum sp., Tistrella mobilis, Treponema sp., or Verminephrobacter eiseniae.

A Cas9 molecule, or Cas9 polypeptide, as that term is used herein, refers to a molecule or a polypeptide that can interact with a guide RNA (gRNA) molecule and, in concert with the gRNA molecule, localizes to a site which comprises a target domain, and in an embodiment, a PAM sequence. Cas9 molecule and Cas9 polypeptide, as those terms are used herein, refer to naturally occurring Cas9 molecules and to engineered, altered, or modified Cas9 molecules or Cas9 polypeptides that differ, e.g., by at least one amino acid residue, from a reference sequence, e.g., the most similar naturally occurring Cas9 molecule or a sequence of Table 28.

Cas9 Domains

Crystal structures have been determined for two different naturally occurring bacterial Cas9 molecules (Jinek et al., Science, 343(6176):1247997, 2014) and for S. pyogenes Cas9 with a guide RNA (e.g., a synthetic fusion of crRNA and tracrRNA) (Nishimasu et al., Cell, 156:935-949, 2014; and Anders et al., Nature, 2014, doi: 10.1038/nature13579).

A naturally occurring Cas9 molecule comprises two lobes: a recognition (REC) lobe and a nuclease (NUC) lobe; each of which further comprise domains described herein. FIGS. 9A-9B provide a schematic of the organization of important Cas9 domains in the primary structure. The domain nomenclature and the numbering of the amino acid residues encompassed by each domain used throughout this disclosure is as described in Nishimasu et al. The numbering of the amino acid residues is with reference to Cas9 from S. pyogenes.

The REC lobe comprises the arginine-rich bridge helix (BH), the REC1 domain, and the REC2 domain. The REC lobe does not share structural similarity with other known proteins, indicating that it is a Cas9-specific functional domain. The BH domain is a long c helix and arginine rich region and comprises amino acids 60-93 of the sequence of S. pyogenes Cas9. The REC1 domain is important for recognition of the repeat:anti-repeat duplex, e.g., of a gRNA or a tracrRNA, and is therefore critical for Cas9 activity by recognizing the target sequence. The REC1 domain comprises two REC1 motifs at amino acids 94 to 179 and 308 to 717 of the sequence of S. pyogenes Cas9. These two REC1 domains, though separated by the REC2 domain in the linear primary structure, assemble in the tertiary structure to form the REC1 domain. The REC2 domain, or parts thereof, may also play a role in the recognition of the repeat:anti-repeat duplex. The REC2 domain comprises amino acids 180-307 of the sequence of S. pyogenes Cas9.

The NUC lobe comprises the RuvC domain, the HNH domain, and the PAM-interacting (PI) domain. The RuvC domain shares structural similarity to retroviral integrase superfamily members and cleaves a single strand, e.g., the non-complementary strand of the target nucleic acid molecule. The RuvC domain is assembled from the three split RuvC motifs (RuvC I, RuvCII, and RuvCIII, which are often commonly referred to in the art as RuvCI domain, or N-terminal RuvC domain, RuvCII domain, and RuvCIII domain) at amino acids 1-59, 718-769, and 909-1098, respectively, of the sequence of S. pyogenes Cas9. Similar to the REC1 domain, the three RuvC motifs are linearly separated by other domains in the primary structure, however in the tertiary structure, the three RuvC motifs assemble and form the RuvC domain. The HNH domain shares structural similarity with HNH endonucleases, and cleaves a single strand, e.g., the complementary strand of the target nucleic acid molecule. The HNH domain lies between the RuvC II-III motifs and comprises amino acids 775-908 of the sequence of S. pyogenes Cas9. The PI domain interacts with the PAM of the target nucleic acid molecule, and comprises amino acids 1099-1368 of the sequence of S. pyogenes Cas9.

A RuvC-Like Domain and an HNH-Like Domain

In an embodiment, a Cas9 molecule or Cas9 polypeptide comprises an HNH-like domain and a RuvC-like domain. In an embodiment, cleavage activity is dependent on a RuvC-like domain and an HNH-like domain. A Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, can comprise one or more of the following domains: a RuvC-like domain and an HNH-like domain. In an embodiment, a Cas9 molecule or Cas9 polypeptide is an eaCas9 molecule or eaCas9 polypeptide and the eaCas9 molecule or eaCas9 polypeptide comprises a RuvC-like domain, e.g., a RuvC-like domain described below, and/or an HNH-like domain, e.g., an HNH-like domain described below.

RuvC-Like Domains

In an embodiment, a RuvC-like domain cleaves, a single strand, e.g., the non-complementary strand of the target nucleic acid molecule. The Cas9 molecule or Cas9 polypeptide can include more than one RuvC-like domain (e.g., one, two, three or more RuvC-like domains). In an embodiment, a RuvC-like domain is at least 5, 6, 7, 8 amino acids in length but not more than 20, 19, 18, 17, 16 or 15 amino acids in length. In an embodiment, the Cas9 molecule or Cas9 polypeptide comprises an N-terminal RuvC-like domain of about 10 to 20 amino acids, e.g., about 15 amino acids in length.

N-Terminal RuvC-Like Domains

Some naturally occurring Cas9 molecules comprise more than one RuvC-like domain with cleavage being dependent on the N-terminal RuvC-like domain. Accordingly, Cas9 molecules or Cas9 polypeptide can comprise an N-terminal RuvC-like domain. Exemplary N-terminal RuvC-like domains are described below.

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises an N-terminal RuvC-like domain comprising an amino acid sequence of formula I:

(SEQ ID NO: 8) D-X1-G-X2-X3-X4-X5-G-X6-X7-X8-X9,

wherein,

X1 is selected from I, V, M, L and T (e.g., selected from I, V, and L);

X2 is selected from T, I, V, S, N, Y, E and L (e.g., selected from T, V, and I);

X3 is selected from N, S, G, A, D, T, R, M and F (e.g., A or N);

X4 is selected from S, Y, N and F (e.g., S);

X5 is selected from V, I, L, C, T and F (e.g., selected from V, I and L);

X6 is selected from W, F, V, Y, S and L (e.g., W);

X7 is selected from A, S, C, V and G (e.g., selected from A and S);

X8 is selected from V, I, L, A, M and H (e.g., selected from V, I, M and L); and

X9 is selected from any amino acid or is absent (e.g., selected from T, V, I, L, Δ, F, S, A, Y, M and R, or, e.g., selected from T, V, I, L and A).

In an embodiment, the N-terminal RuvC-like domain differs from a sequence of SEQ ID NO:8, by as many as 1 but no more than 2, 3, 4, or 5 residues.

In embodiment, the N-terminal RuvC-like domain is cleavage competent.

In embodiment, the N-terminal RuvC-like domain is cleavage incompetent.

In an embodiment, a eaCas9 molecule or eaCas9 polypeptide comprises an N-terminal RuvC-like domain comprising an amino acid sequence of formula II:

(SEQ ID NO: 9) D-X1-G-X2-X3-S-X5-G-X6-X7-X8-X9,,

wherein

X1 is selected from I, V, M, L and T (e.g., selected from I, V, and L);

X2 is selected from T, I, V, S, N, Y, E and L (e.g., selected from T, V, and I);

X3 is selected from N, S, G, A, D, T, R, M and F (e.g., A or N);

X5 is selected from V, I, L, C, T and F (e.g., selected from V, I and L);

X6 is selected from W, F, V, Y, S and L (e.g., W);

X7 is selected from A, S, C, V and G (e.g., selected from A and S);

X8 is selected from V, I, L, A, M and H (e.g., selected from V, I, M and L); and

X9 is selected from any amino acid or is absent (e.g., selected from T, V, I, L, Δ, F, S, A,

Y, M and R or selected from e.g., T, V, I, L and A).

In an embodiment, the N-terminal RuvC-like domain differs from a sequence of SEQ ID NO:9 by as many as 1 but no more than 2, 3, 4, or 5 residues.

In an embodiment, the N-terminal RuvC-like domain comprises an amino acid sequence of formula III:

(SEQ ID NO: 10) D-I-G-X2-X3-S-V-G-W-A-X8-X9,

wherein

X2 is selected from T, I, V, S, N, Y, E and L (e.g., selected from T, V, and I);

X3 is selected from N, S, G, A, D, T, R, M and F (e.g., A or N);

X8 is selected from V, I, L, A, M and H (e.g., selected from V, I, M and L); and

X9 is selected from any amino acid or is absent (e.g., selected from T, V, I, L, Δ, F, S, A, Y, M and R or selected from e.g., T, V, I, L and Δ).

In an embodiment, the N-terminal RuvC-like domain differs from a sequence of SEQ ID NO:10 by as many as 1 but no more than, 2, 3, 4, or 5 residues.

In an embodiment, the N-terminal RuvC-like domain comprises an amino acid sequence of formula III:

(SEQ ID NO: 11) D-I-G-T-N-S-V-G-W-A-V-X,

wherein

X is a non-polar alkyl amino acid or a hydroxyl amino acid, e.g., X is selected from V, I, L and T (e.g., the eaCas9 molecule can comprise an N-terminal RuvC-like domain shown in FIGS. 2A-2G (is depicted as Y)).

In an embodiment, the N-terminal RuvC-like domain differs from a sequence of SEQ ID NO:11 by as many as 1 but no more than, 2, 3, 4, or 5 residues.

In an embodiment, the N-terminal RuvC-like domain differs from a sequence of an N-terminal RuvC like domain disclosed herein, e.g., in FIGS. 3A-3B or FIGS. 7A-7B, as many as 1 but no more than 2, 3, 4, or 5 residues. In an embodiment, 1, 2, 3 or all of the highly conserved residues identified in FIGS. 3A-3B or FIGS. 7A-7B are present.

In an embodiment, the N-terminal RuvC-like domain differs from a sequence of an N-terminal RuvC-like domain disclosed herein, e.g., in FIGS. 4A-4B or FIGS. 7A-7B, as many as 1 but no more than 2, 3, 4, or 5 residues. In an embodiment, 1, 2, or all of the highly conserved residues identified in FIGS. 4A-4B or FIGS. 7A-7B are present.

Additional RuvC-Like Domains

In addition to the N-terminal RuvC-like domain, the Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, can comprise one or more additional RuvC-like domains. In an embodiment, the Cas9 molecule or Cas9 polypeptide can comprise two additional RuvC-like domains. Preferably, the additional RuvC-like domain is at least 5 amino acids in length and, e.g., less than 15 amino acids in length, e.g., 5 to 10 amino acids in length, e.g., 8 amino acids in length.

An additional RuvC-like domain can comprise an amino acid sequence:

(SEQ ID NO: 12) I-X1-X2-E-X3-A-R-E, wherein

X1 is V or H,

X2 is I, L or V (e.g., I or V); and

X3 is M or T.

In an embodiment, the additional RuvC-like domain comprises the amino acid sequence:

(SEQ ID NO: 13) I-V-X2-E-M-A-R-E, wherein

X2 is I, L or V (e.g., I or V) (e.g., the eaCas9 molecule or eaCas9 polypeptide can comprise an additional RuvC-like domain shown in FIG. 2A-2G or FIGS. 7A-7B (depicted as B)).

An additional RuvC-like domain can comprise an amino acid sequence:

(SEQ ID NO: 14) H-H-A-X1-D-A-X2-X3, wherein

X1 is H or L;

X2 is R or V; and

X3 is E or V.

In an embodiment, the additional RuvC-like domain comprises the amino acid sequence:

 (SEQ ID NO: 15) H-H-A-H-D-A-Y-L.

In an embodiment, the additional RuvC-like domain differs from a sequence of SEQ ID NO: 12, 13, 14 or 15 by as many as 1 but no more than 2, 3, 4, or 5 residues.

In some embodiments, the sequence flanking the N-terminal RuvC-like domain is a sequences of formula V:

(SEQ ID NO: 16) K-X1′-Y-X2′-X3′-X4′-Z-T-D-X9′-Y,.

wherein

X1′ is selected from K and P,

X2′ is selected from V, L, I, and F (e.g., V, I and L);

X3′ is selected from G, A and S (e.g., G),

X4′ is selected from L, I, V and F (e.g., L);

X9′ is selected from D, E, N and Q; and

Z is an N-terminal RuvC-like domain, e.g., as described above.

HNH-Like Domains

In an embodiment, an HNH-like domain cleaves a single stranded complementary domain, e.g., a complementary strand of a double stranded nucleic acid molecule. In an embodiment, an HNH-like domain is at least 15, 20, 25 amino acids in length but not more than 40, 35 or 30 amino acids in length, e.g., 20 to 35 amino acids in length, e.g., 25 to 30 amino acids in length. Exemplary HNH-like domains are described below.

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises an HNH-like domain having an amino acid sequence of formula VI:

(SEQ ID NO: 17) X1-X2-X3-H-X4-X5-P-X6-X7-X8-X9-X10-X11-X12-X13- X14-X15-N-X16-X17-X18-X19-X20-X21-X22-X23-N, wherein

X1 is selected from D, E, Q and N (e.g., D and E);

X2 is selected from L, I, R, Q, V, M and K;

X3 is selected from D and E;

X4 is selected from I, V, T, A and L (e.g., A, I and V);

X5 is selected from V, Y, I, L, F and W (e.g., V, I and L);

X6 is selected from Q, H, R, K, Y, I, L, F and W;

X7 is selected from S, A, D, T and K (e.g., S and A);

X8 is selected from F, L, V, K, Y, M, I, R, A, E, D and Q (e.g., F);

X9 is selected from L, R, T, I, V, S, C, Y, K, F and G;

X10 is selected from K, Q, Y, T, F, L, W, M, A, E, G, and S;

X11 is selected from D, S, N, R, L and T (e.g., D);

X12 is selected from D, N and S;

X13 is selected from S, A, T, G and R (e.g., S);

X14 is selected from I, L, F, S, R, Y, Q, W, D, K and H (e.g., I, L and F);

X15 is selected from D, S, I, N, E, A, H, F, L, Q, M, G, Y and V;

X16 is selected from K, L, R, M, T and F (e.g., L, R and K);

X17 is selected from V, L, I, A and T;

X18 is selected from L, I, V and A (e.g., L and I);

X19 is selected from T, V, C, E, S and A (e.g., T and V);

X20 is selected from R, F, T, W, E, L, N, C, K, V, S, Q, I, Y, H and A;

X21 is selected from S, P, R, K, N, A, H, Q, G and L;

X22 is selected from D, G, T, N, S, K, A, I, E, L, Q, R and Y; and

X23 is selected from K, V, A, E, Y, I, C, L, S, T, G, K, M, D and F.

In an embodiment, a HNH-like domain differs from a sequence of SEQ ID NO: 17 by at least one but no more than, 2, 3, 4, or 5 residues.

In an embodiment, the HNH-like domain is cleavage competent.

In an embodiment, the HNH-like domain is cleavage incompetent.

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises an HNH-like domain comprising an amino acid sequence of formula VII:

(SEQ ID NO: 18) X1-X2-X3-H-X4-X5-P-X6-S-X8-X9-X10-D-D-S-X14-X15- N-K-V-L-X19-X20-X21-X22-X23-N,

wherein

X1 is selected from D and E;

X2 is selected from L, I, R, Q, V, M and K;

X3 is selected from D and E;

X4 is selected from I, V, T, A and L (e.g., A, I and V);

X5 is selected from V, Y, I, L, F and W (e.g., V, I and L);

X6 is selected from Q, H, R, K, Y, I, L, F and W;

X8 is selected from F, L, V, K, Y, M, I, R, A, E, D and Q (e.g., F);

X9 is selected from L, R, T, I, V, S, C, Y, K, F and G;

X10 is selected from K, Q, Y, T, F, L, W, M, A, E, G, and S;

X14 is selected from I, L, F, S, R, Y, Q, W, D, K and H (e.g., I, L and F);

X15 is selected from D, S, I, N, E, A, H, F, L, Q, M, G, Y and V;

X19 is selected from T, V, C, E, S and A (e.g., T and V);

X20 is selected from R, F, T, W, E, L, N, C, K, V, S, Q, I, Y, H and A;

X21 is selected from S, P, R, K, N, A, H, Q, G and L;

X22 is selected from D, G, T, N, S, K, A, I, E, L, Q, R and Y; and

X23 is selected from K, V, A, E, Y, I, C, L, S, T, G, K, M, D and F.

In an embodiment, the HNH-like domain differs from a sequence of SEQ ID NO: 18 by 1, 2, 3, 4, or 5 residues.

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises an HNH-like domain comprising an amino acid sequence of formula VII:

(SEQ ID NO: 19) X1-V-X3-H-I-V-P-X6-S-X8-X9-X10-D-D-S-X14-X15-N-K- V-L-T-X20-X21-X22-X23-N,

wherein

X1 is selected from D and E;

X3 is selected from D and E;

X6 is selected from Q, H, R, K, Y, I, L and W;

X8 is selected from F, L, V, K, Y, M, I, R, A, E, D and Q (e.g., F);

X9 is selected from L, R, T, I, V, S, C, Y, K, F and G;

X10 is selected from K, Q, Y, T, F, L, W, M, A, E, G, and S;

X14 is selected from I, L, F, S, R, Y, Q, W, D, K and H (e.g., I, L and F);

X15 is selected from D, S, I, N, E, A, H, F, L, Q, M, G, Y and V;

X20 is selected from R, F, T, W, E, L, N, C, K, V, S, Q, I, Y, H and A;

X21 is selected from S, P, R, K, N, A, H, Q, G and L;

X22 is selected from D, G, T, N, S, K, A, I, E, L, Q, R and Y; and

X23 is selected from K, V, A, E, Y, I, C, L, S, T, G, K, M, D and F.

In an embodiment, the HNH-like domain differs from a sequence of SEQ ID NO: 19 by 1, 2, 3, 4, or 5 residues.

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises an HNH-like domain having an amino acid sequence of formula VIII:

(SEQ ID NO: 20) D-X2-D-H-I-X5-P-Q-X7-F-X9-X10-D-X12-S-I-D-N-X16- V-L-X19-X20-S-X22-X23-N,

wherein

X2 is selected from I and V;

X5 is selected from I and V;

X7 is selected from A and S;

X9 is selected from I and L;

X10 is selected from K and T;

X12 is selected from D and N;

X16 is selected from R, K and L; X19 is selected from T and V;

X20 is selected from S and R;

X22 is selected from K, D and A; and

X23 is selected from E, K, G and N (e.g., the eaCas9 molecule or eaCas9 polypeptide can comprise an HNH-like domain as described herein).

In an embodiment, the HNH-like domain differs from a sequence of SEQ ID NO: 20 by as many as 1 but no more than 2, 3, 4, or 5 residues.

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises the amino acid sequence of formula IX:

(SEQ ID NO: 21) L-Y-Y-L-Q-N-G-X1’-D-M-Y-X2’-X3’-X4’-X5’-L-D-I- X6’-X7’-L-S-X8’-Y-Z-N-R-X9’-K-X10’-D-X11’-V-P,

wherein

X1′ is selected from K and R;

X2′ is selected from V and T;

X3′ is selected from G and D;

X4′ is selected from E, Q and D;

X5′ is selected from E and D;

X6′ is selected from D, N and H;

X7′ is selected from Y, R and N;

X8′ is selected from Q, D and N; X9′ is selected from G and E;

X10′ is selected from S and G;

X11′ is selected from D and N; and

Z is an HNH-like domain, e.g., as described above.

In an embodiment, the eaCas9 molecule or eaCas9 polypeptide comprises an amino acid sequence that differs from a sequence of SEQ ID NO:21 by as many as 1 but no more than 2, 3, 4, or 5 residues.

In an embodiment, the HNH-like domain differs from a sequence of an HNH-like domain disclosed herein, e.g., in FIGS. 5A-5C or FIGS. 7A-7B, as many as 1 but no more than 2, 3, 4, or 5 residues. In an embodiment, 1 or both of the highly conserved residues identified in FIGS. 5A-5C or FIGS. 7A-7B are present.

In an embodiment, the HNH-like domain differs from a sequence of an HNH-like domain disclosed herein, e.g., in FIGS. 6A-6B or FIGS. 7A-7B, as many as 1 but no more than 2, 3, 4, or 5 residues. In an embodiment, 1, 2, all 3 of the highly conserved residues identified in FIGS. 6A-6B or FIGS. 7A-7B are present.

Cas9 Activities

Nuclease and Helicase Activities

In an embodiment, the Cas9 molecule or Cas9 polypeptide is capable of cleaving a target nucleic acid molecule. Typically wild type Cas9 molecules cleave both strands of a target nucleic acid molecule. Cas9 molecules and Cas9 polypeptides can be engineered to alter nuclease cleavage (or other properties), e.g., to provide a Cas9 molecule or Cas9 polypeptide which is a nickase, or which lacks the ability to cleave target nucleic acid. A Cas9 molecule or Cas9 polypeptide that is capable of cleaving a target nucleic acid molecule is referred to herein as an eaCas9 (an enzymatically active Cas9) molecule or eaCas9 polypeptide.

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises one or more of the following enzymatic activities:

a nickase activity, i.e., the ability to cleave a single strand, e.g., the non-complementary strand or the complementary strand, of a nucleic acid molecule;

a double stranded nuclease activity, i.e., the ability to cleave both strands of a double stranded nucleic acid and create a double stranded break, which in an embodiment is the presence of two nickase activities;

an endonuclease activity;

an exonuclease activity; and

a helicase activity, i.e., the ability to unwind the helical structure of a double stranded nucleic acid.

In an embodiment, an enzymatically active or an eaCas9 molecule or eaCas9 polypeptide cleaves both DNA strands and results in a double stranded break. In an embodiment, an eaCas9 molecule or eaCas9 polypeptide cleaves only one strand, e.g., the strand to which the gRNA hybridizes to, or the strand complementary to the strand the gRNA hybridizes with. In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises cleavage activity associated with an HNH domain. In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises cleavage activity associated with a RuvC domain. In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises cleavage activity associated with an HNH domain and cleavage activity associated with a RuvC domain. In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises an active, or cleavage competent, HNH domain and an inactive, or cleavage incompetent, RuvC domain. In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises an inactive, or cleavage incompetent, HNH domain and an active, or cleavage competent, RuvC domain.

Some Cas9 molecules or Cas9 polypeptides have the ability to interact with a gRNA molecule, and in conjunction with the gRNA molecule localize to a core target domain, but are incapable of cleaving the target nucleic acid, or incapable of cleaving at efficient rates. Cas9 molecules having no, or no substantial, cleavage activity are referred to herein as an eiCas9 molecule or eiCas9 polypeptide. For example, an eiCas9 molecule or eiCas9 polypeptide can lack cleavage activity or have substantially less, e.g., less than 20, 10, 5, 1 or 0.1% of the cleavage activity of a reference Cas9 molecule or eiCas9 polypeptide, as measured by an assay described herein.

Targeting And PAMs

A Cas9 molecule or Cas9 polypeptide, is a polypeptide that can interact with a guide RNA (gRNA) molecule and, in concert with the gRNA molecule, localizes to a site which comprises a target domain, and in an embodiment, a PAM sequence.

In an embodiment, the ability of an eaCas9 molecule or eaCas9 polypeptide to interact with and cleave a target nucleic acid is PAM sequence dependent. A PAM sequence is a sequence in the target nucleic acid. In an embodiment, cleavage of the target nucleic acid occurs upstream from the PAM sequence. EaCas9 molecules from different bacterial species can recognize different sequence motifs (e.g., PAM sequences). In an embodiment, an eaCas9 molecule of S. pyogenes recognizes the sequence motif NGG and directs cleavage of a target nucleic acid sequence 1 to 10, e.g., 3 to 5, base pairs upstream from that sequence. See, e.g., Mali et al., SCIENCE 2013; 339(6121): 823-826. In an embodiment, an eaCas9 molecule of S. thermophilus recognizes the sequence motif NGGNG (SEQ ID NO.: 90) and/or NNAGAAW (W=A or T) (SEQ ID NO.: 91) and directs cleavage of a target nucleic acid sequence 1 to 10, e.g., 3 to 5, base pairs upstream from these sequences. See, e.g., Horvath et al., SCIENCE 2010; 327(5962):167-170, and Deveau et al., J BACTERIOL 2008; 190(4): 1390-1400. In an embodiment, an eaCas9 molecule of S. mutans recognizes the sequence motif NGG and/or NAAR (R=A or G) (SEQ ID NO.: 92) and directs cleavage of a target nucleic acid sequence 1 to 10, e.g., 3 to 5 base pairs, upstream from this sequence. See, e.g., Deveau et al., J BACTERIOL 2008; 190(4): 1390-1400. In an embodiment, an eaCas9 molecule of S. aureus recognizes the sequence motif NNGRR (R=A or G) (SEQ ID NO.: 93) and directs cleavage of a target nucleic acid sequence 1 to 10, e.g., 3 to 5, base pairs upstream from that sequence. In an embodiment, an eaCas9 molecule of S. aureus recognizes the sequence motif NNGRRN (R=A or G) and directs cleavage of a target nucleic acid sequence 1 to 10, e.g., 3 to 5, base pairs upstream from that sequence. In an embodiment, an eaCas9 molecule of S. aureus recognizes the sequence motif NNGRRT (R=A or G) and directs cleavage of a target nucleic acid sequence 1 to 10, e.g., 3 to 5, base pairs upstream from that sequence. In an embodiment, an eaCas9 molecule of S. aureus recognizes the sequence motif NNGRRV (R=A or G) (SEQ ID NO.:) and directs cleavage of a target nucleic acid sequence 1 to 10, e.g., 3 to 5, base pairs upstream from that sequence. In an embodiment, an eaCas9 molecule of N. meningitidis recognizes the sequence motif NNNNGATT (SEQ ID NO.: 94) or NNNGCTT (R=A or G) (SEQ ID NO: 95) and directs cleavage of a target nucleic acid sequence 1 to 10, e.g., 3 to 5, base pairs upstream from that sequence. See, e.g., Hou et al., PNAS 2013; 110(39):15644-15649. The ability of a Cas9 molecule to recognize a PAM sequence can be determined, e.g., using a transformation assay described in Jinek et al., SCIENCE 2012, 337:816. In the aforementioned embodiments, N can be any nucleotide residue, e.g., any of A, G, C or T.

As is discussed herein, Cas9 molecules can be engineered to alter the PAM specificity of the Cas9 molecule.

Exemplary naturally occurring Cas9 molecules are described in Chylinski et al., RNA BIOLOGY 2013 10:5, 727-737. Such Cas9 molecules include Cas9 molecules of a cluster 1 bacterial family, cluster 2 bacterial family, cluster 3 bacterial family, cluster 4 bacterial family, cluster 5 bacterial family, cluster 6 bacterial family, a cluster 7 bacterial family, a cluster 8 bacterial family, a cluster 9 bacterial family, a cluster 10 bacterial family, a cluster 11 bacterial family, a cluster 12 bacterial family, a cluster 13 bacterial family, a cluster 14 bacterial family, a cluster 15 bacterial family, a cluster 16 bacterial family, a cluster 17 bacterial family, a cluster 18 bacterial family, a cluster 19 bacterial family, a cluster 20 bacterial family, a cluster 21 bacterial family, a cluster 22 bacterial family, a cluster 23 bacterial family, a cluster 24 bacterial family, a cluster 25 bacterial family, a cluster 26 bacterial family, a cluster 27 bacterial family, a cluster 28 bacterial family, a cluster 29 bacterial family, a cluster 30 bacterial family, a cluster 31 bacterial family, a cluster 32 bacterial family, a cluster 33 bacterial family, a cluster 34 bacterial family, a cluster 35 bacterial family, a cluster 36 bacterial family, a cluster 37 bacterial family, a cluster 38 bacterial family, a cluster 39 bacterial family, a cluster 40 bacterial family, a cluster 41 bacterial family, a cluster 42 bacterial family, a cluster 43 bacterial family, a cluster 44 bacterial family, a cluster 45 bacterial family, a cluster 46 bacterial family, a cluster 47 bacterial family, a cluster 48 bacterial family, a cluster 49 bacterial family, a cluster 50 bacterial family, a cluster 51 bacterial family, a cluster 52 bacterial family, a cluster 53 bacterial family, a cluster 54 bacterial family, a cluster 55 bacterial family, a cluster 56 bacterial family, a cluster 57 bacterial family, a cluster 58 bacterial family, a cluster 59 bacterial family, a cluster 60 bacterial family, a cluster 61 bacterial family, a cluster 62 bacterial family, a cluster 63 bacterial family, a cluster 64 bacterial family, a cluster 65 bacterial family, a cluster 66 bacterial family, a cluster 67 bacterial family, a cluster 68 bacterial family, a cluster 69 bacterial family, a cluster 70 bacterial family, a cluster 71 bacterial family, a cluster 72 bacterial family, a cluster 73 bacterial family, a cluster 74 bacterial family, a cluster 75 bacterial family, a cluster 76 bacterial family, a cluster 77 bacterial family, or a cluster 78 bacterial family.

Exemplary naturally occurring Cas9 molecules include a Cas9 molecule of a cluster 1 bacterial family. Examples include a Cas9 molecule of: S. pyogenes (e.g., strain SF370, MGAS10270, MGAS10750, MGAS2096, MGAS315, MGAS5005, MGAS6180, MGAS9429, NZ131 and SSI-1), S. thermophilus (e.g., strain LMD-9), S. pseudoporcinus (e.g., strain SPIN 20026), S. mutans (e.g., strain UA159, NN2025), S. macacae (e.g., strain NCTC11558), S. gallolyticus (e.g., strain UCN34, ATCC BAA-2069), S. equines (e.g., strain ATCC 9812, MGCS 124), S. dysdalactiae (e.g., strain GGS 124), S. bovis (e.g., strain ATCC 700338), S. anginosus (e.g., strain F0211), S. agalactiae (e.g., strain NEM316, A909), Listeria monocytogenes (e.g., strain F6854), Listeria innocua (L. innocua, e.g., strain Clip11262), Enterococcus italicus (e.g., strain DSM 15952), or Enterococcus faecium (e.g., strain 1,231,408). Additional exemplary Cas9 molecules are a Cas9 molecule of Neisseria meningitidis (Hou et al., PNAS Early Edition 2013, 1-6 and a S. aureus cas9 molecule.

In an embodiment, a Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, comprises an amino acid sequence: having 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98% or 99% homology with;

differs at no more than, 2, 5, 10, 15, 20, 30, or 40% of the amino acid residues when compared with;

differs by at least 1, 2, 5, 10 or 20 amino acids, but by no more than 100, 80, 70, 60, 50, 40 or 30 amino acids from; or

is identical to any Cas9 molecule sequence described herein, or a naturally occurring Cas9 molecule sequence, e.g., a Cas9 molecule from a species listed herein or described in Chylinski et al., RNA BIOLOGY 2013 10:5, 727-737; Hou et al., PNAS Early Edition 2013, 1-6; SEQ ID NO:1-4. In an embodiment, the Cas9 molecule or Cas9 polypeptide comprises one or more of the following activities: a nickase activity; a double stranded cleavage activity (e.g., an endonuclease and/or exonuclease activity); a helicase activity; or the ability, together with a gRNA molecule, to localize to a target nucleic acid.

In an embodiment, a Cas9 molecule or Cas9 polypeptide comprises any of the amino acid sequence of the consensus sequence of FIGS. 2A-2G, wherein “*” indicates any amino acid found in the corresponding position in the amino acid sequence of a Cas9 molecule of S. pyogenes, S. thermophilus, S. mutans and L. innocua, and “-” indicates any amino acid. In an embodiment, a Cas9 molecule or Cas9 polypeptide differs from the sequence of the consensus sequence disclosed in FIGS. 2A-2G by at least 1, but no more than 2, 3, 4, 5, 6, 7, 8, 9, or 10 amino acid residues. In an embodiment, a Cas9 molecule or Cas9 polypeptide comprises the amino acid sequence of SEQ ID NO:7 of FIGS. 7A-7B, wherein “*” indicates any amino acid found in the corresponding position in the amino acid sequence of a Cas9 molecule of S. pyogenes, or N. meningitidis, “-” indicates any amino acid, and “-” indicates any amino acid or absent. In an embodiment, a Cas9 molecule or Cas9 polypeptide differs from the sequence of SEQ ID NO:6 or 7 disclosed in FIGS. 7A-7B by at least 1, but no more than 2, 3, 4, 5, 6, 7, 8, 9, or 10 amino acid residues.

A comparison of the sequence of a number of Cas9 molecules indicate that certain regions are conserved. These are identified below as:

region 1 (residues1 to 180, or in the case of region 1'residues 120 to 180)

region 2 (residues360 to 480);

region 3 (residues 660 to 720);

region 4 (residues 817 to 900); and

region 5 (residues 900 to 960);

In an embodiment, a Cas9 molecule or Cas9 polypeptide comprises regions 1-5, together with sufficient additional Cas9 molecule sequence to provide a biologically active molecule, e.g., a Cas9 molecule having at least one activity described herein. In an embodiment, each of regions 1-5, independently, have 50%, 60%, 70%, 80%, 85%, 90%, 95%, 96%, 97%, 98% or 99% homology with the corresponding residues of a Cas9 molecule or Cas9 polypeptide described herein, e.g., a sequence from FIGS. 2A-2G or from FIGS. 7A-7B.

In an embodiment, a Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, comprises an amino acid sequence referred to as region 1:

having 50%, 60%, 70%, 80%, 85%, 90%, 95%, 96%, 97%, 98% or 99% homology with amino acids 1-180 (the numbering is according to the motif sequence in FIG. 2 ; 52% of residues in the four Cas9 sequences in FIGS. 2A-2G are conserved) of the amino acid sequence of Cas9 of S. pyogenes;

differs by at least 1, 2, 5, 10 or 20 amino acids but by no more than 90, 80, 70, 60, 50, 40 or 30 amino acids from amino acids 1-180 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or Listeria innocua; or

is identical to 1-180 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua.

In an embodiment, a Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, comprises an amino acid sequence referred to as region 1′:

having 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98% or 99% homology with amino acids 120-180 (55% of residues in the four Cas9 sequences in FIG. 2 are conserved) of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua;

differs by at least 1, 2, or 5 amino acids but by no more than 35, 30, 25, 20 or 10 amino acids from amino acids 120-180 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua; or

is identical to 120-180 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua.

In an embodiment, a Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, comprises an amino acid sequence referred to as region 2: having 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98% or 99% homology with amino acids 360-480 (52% of residues in the four Cas9 sequences in FIG. 2 are conserved) of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua;

differs by at least 1, 2, or 5 amino acids but by no more than 35, 30, 25, 20 or 10 amino acids from amino acids 360-480 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua; or

is identical to 360-480 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua.

In an embodiment, a Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, comprises an amino acid sequence referred to as region 3:

having 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98%, or 99% homology with amino acids 660-720 (56% of residues in the four Cas9 sequences in FIG. 2 are conserved) of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua;

differs by at least 1, 2, or 5 amino acids but by no more than 35, 30, 25, 20 or 10 amino acids from amino acids 660-720 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua; or

is identical to 660-720 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua.

In an embodiment, a Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, comprises an amino acid sequence referred to as region 4:

having 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98%, or 99% homology with amino acids 817-900 (55% of residues in the four Cas9 sequences in FIGS. 2A-2G are conserved) of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua;

differs by at least 1, 2, or 5 amino acids but by no more than 35, 30, 25, 20 or 10 amino acids from amino acids 817-900 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua; or

is identical to 817-900 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua.

In an embodiment, a Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, comprises an amino acid sequence referred to as region 5:

having 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98%, or 99% homology with amino acids 900-960 (60% of residues in the four Cas9 sequences in FIGS. 2A-2G are conserved) of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua;

differs by at least 1, 2, or 5 amino acids but by no more than 35, 30, 25, 20 or 10 amino acids from amino acids 900-960 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua; or

is identical to 900-960 of the amino acid sequence of Cas9 of S. pyogenes, S. thermophilus, S. mutans or L. innocua.

Engineered Or Altered Cas9 Molecules And Cas9 Polypeptides

Cas9 molecules and Cas9 polypeptides described herein, e.g., naturally occurring Cas9 molecules, can possess any of a number of properties, including: nuclease activity (e.g., endonuclease and/or exonuclease activity); helicase activity; the ability to associate functionally with a gRNA molecule; and the ability to target (or localize to) a site on a nucleic acid (e.g., PAM recognition and specificity). In an embodiment, a Cas9 molecule or Cas9 polypeptide can include all or a subset of these properties. In a typical embodiment, a Cas9 molecule or Cas9 polypeptide has the ability to interact with a gRNA molecule and, in concert with the gRNA molecule, localize to a site in a nucleic acid. Other activities, e.g., PAM specificity, cleavage activity, or helicase activity can vary more widely in Cas9 molecules and Cas9 polypeptides.

Cas9 molecules include engineered Cas9 molecules and engineered Cas9 polypeptides (engineered, as used in this context, means merely that the Cas9 molecule or Cas9 polypeptide differs from a reference sequences, and implies no process or origin limitation). An engineered Cas9 molecule or Cas9 polypeptide can comprise altered enzymatic properties, e.g., altered nuclease activity, (as compared with a naturally occurring or other reference Cas9 molecule) or altered helicase activity. As discussed herein, an engineered Cas9 molecule or Cas9 polypeptide can have nickase activity (as opposed to double strand nuclease activity). In an embodiment an engineered Cas9 molecule or Cas9 polypeptide can have an alteration that alters its size, e.g., a deletion of amino acid sequence that reduces its size, e.g., without significant effect on one or more, or any Cas9 activity. In an embodiment, an engineered Cas9 molecule or Cas9 polypeptide can comprise an alteration that affects PAM recognition. E.g., an engineered Cas9 molecule can be altered to recognize a PAM sequence other than that recognized by the endogenous wild-type PI domain. In an embodiment a Cas9 molecule or Cas9 polypeptide can differ in sequence from a naturally occurring Cas9 molecule but not have significant alteration in one or more Cas9 activities.

Cas9 molecules or Cas9 polypeptides with desired properties can be made in a number of ways, e.g., by alteration of a parental, e.g., naturally occurring, Cas9 molecules or Cas9 polypeptides, to provide an altered Cas9 molecule or Cas9 polypeptide having a desired property. For example, one or more mutations or differences relative to a parental Cas9 molecule, e.g., a naturally occurring or engineered Cas9 molecule, can be introduced. Such mutations and differences comprise: substitutions (e.g., conservative substitutions or substitutions of non-essential amino acids); insertions; or deletions. In an embodiment, a Cas9 molecule or Cas9 polypeptide can comprises one or more mutations or differences, e.g., at least 1, 2, 3, 4, 5, 10, 15, 20, 30, 40 or 50 mutations but less than 200, 100, or 80 mutations relative to a reference, e.g., a parental, Cas9 molecule.

In an embodiment, a mutation or mutations do not have a substantial effect on a Cas9 activity, e.g. a Cas9 activity described herein. In an embodiment, a mutation or mutations have a substantial effect on a Cas9 activity, e.g. a Cas9 activity described herein.

Non-Cleaving and Modified-Cleavage Cas9 Molecules and Cas9 Polypeptides

In an embodiment, a Cas9 molecule or Cas9 polypeptide comprises a cleavage property that differs from naturally occurring Cas9 molecules, e.g., that differs from the naturally occurring Cas9 molecule having the closest homology. For example, a Cas9 molecule or Cas9 polypeptide can differ from naturally occurring Cas9 molecules, e.g., a Cas9 molecule of S. pyogenes, as follows: its ability to modulate, e.g., decreased or increased, cleavage of a double stranded nucleic acid (endonuclease and/or exonuclease activity), e.g., as compared to a naturally occurring Cas9 molecule (e.g., a Cas9 molecule of S. pyogenes); its ability to modulate, e.g., decreased or increased, cleavage of a single strand of a nucleic acid, e.g., a non-complementary strand of a nucleic acid molecule or a complementary strand of a nucleic acid molecule (nickase activity), e.g., as compared to a naturally occurring Cas9 molecule (e.g., a Cas9 molecule of S. pyogenes); or the ability to cleave a nucleic acid molecule, e.g., a double stranded or single stranded nucleic acid molecule, can be eliminated.

Modified Cleavage eaCas9 Molecules and eaCas9 Polypeptides

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises one or more of the following activities: cleavage activity associated with an N-terminal RuvC-like domain; cleavage activity associated with an HNH-like domain; cleavage activity associated with an HNH-like domain and cleavage activity associated with an N-terminal RuvC-like domain.

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises an active, or cleavage competent, HNH-like domain (e.g., an HNH-like domain described herein, e.g., SEQ ID NO: 17, SEQ ID NO: 18, SEQ ID NO: 19, SEQ ID NO: 20 or SEQ ID NO: 21) and an inactive, or cleavage incompetent, N-terminal RuvC-like domain. An exemplary inactive, or cleavage incompetent N-terminal RuvC-like domain can have a mutation of an aspartic acid in an N-terminal RuvC-like domain, e.g., an aspartic acid at position 9 of the consensus sequence disclosed in FIGS. 2A-2G or an aspartic acid at position 10 of SEQ ID NO: 7, e.g., can be substituted with an alanine. In an embodiment, the eaCas9 molecule or eaCas9 polypeptide differs from wild type in the N-terminal RuvC-like domain and does not cleave the target nucleic acid, or cleaves with significantly less efficiency, e.g., less than 20, 10, 5, 1 or 0.1% of the cleavage activity of a reference Cas9 molecule, e.g., as measured by an assay described herein. The reference Cas9 molecule can by a naturally occurring unmodified Cas9 molecule, e.g., a naturally occurring Cas9 molecule such as a Cas9 molecule of S. pyogenes, or S. thermophilus. In an embodiment, the reference Cas9 molecule is the naturally occurring Cas9 molecule having the closest sequence identity or homology.

In an embodiment, an eaCas9 molecule or eaCas9 polypeptide comprises an inactive, or cleavage incompetent, HNH domain and an active, or cleavage competent, N-terminal RuvC-like domain (e.g., a RuvC-like domain described herein, e.g., SEQ ID NO: 8, SEQ ID NO: 9, SEQ ID NO: 10, SEQ ID NO: 11, SEQ ID NO: 12, SEQ ID NO: 13, SEQ ID NO: 14, SEQ ID NO: 15, or SEQ ID NO: 16). Exemplary inactive, or cleavage incompetent HNH-like domains can have a mutation at one or more of: a histidine in an HNH-like domain, e.g., a histidine shown at position 856 of the consensus sequence disclosed in FIGS. 2A-2G, e.g., can be substituted with an alanine; and one or more asparagines in an HNH-like domain, e.g., an asparagine shown at position 870 of the consensus sequence disclosed in FIGS. 2A-2G and/or at position 879 of the consensus sequence disclosed in FIGS. 2A-2G, e.g., can be substituted with an alanine. In an embodiment, the eaCas9 differs from wild type in the HNH-like domain and does not cleave the target nucleic acid, or cleaves with significantly less efficiency, e.g., less than 20, 10, 5, 1 or 0.1% of the cleavage activity of a reference Cas9 molecule, e.g., as measured by an assay described herein. The reference Cas9 molecule can by a naturally occurring unmodified Cas9 molecule, e.g., a naturally occurring Cas9 molecule such as a Cas9 molecule of S. pyogenes, or S. thermophilus. In an embodiment, the reference Cas9 molecule is the naturally occurring Cas9 molecule having the closest sequence identity or homology.

Alterations in the Ability to Cleave One or Both Strands of a Target Nucleic Acid

In an embodiment, exemplary Cas9 activities comprise one or more of PAM specificity, cleavage activity, and helicase activity. A mutation(s) can be present, e.g., in: one or more RuvC domains, e.g., an N-terminal RuvC domain; an HNH domain; a region outside the RuvC domains and the HNH domain. In an embodiment, a mutation(s) is present in a RuvC domain. In an embodiment, a mutation(s) is present in an HNH domain. In an embodiment, mutations are present in both a RuvC domain and an HNH domain.

Exemplary mutations that may be made in the RuvC domain or HNH domain with reference to the S. pyogenes sequence include: D10A, E762A, H840A, N854A, N863A and/or D986A.

In an embodiment, a Cas9 molecule is an eiCas9 molecule comprising one or more differences in a RuvC domain and/or in an HNH domain as compared to a reference Cas9 molecule, and the eiCas9 molecule does not cleave a nucleic acid, or cleaves with significantly less efficiency than does wildtype, e.g., when compared with wild type in a cleavage assay, e.g., as described herein, cuts with less than 50, 25, 10, or 1% of a reference Cas9 molecule, as measured by an assay described herein.

Whether or not a particular sequence, e.g., a substitution, may affect one or more activity, such as targeting activity, cleavage activity, etc, can be evaluated or predicted, e.g., by evaluating whether the mutation is conservative. In an embodiment, a “non-essential” amino acid residue, as used in the context of a Cas9 molecule, is a residue that can be altered from the wild-type sequence of a Cas9 molecule, e.g., a naturally occurring Cas9 molecule, e.g., an eaCas9 molecule, without abolishing or more preferably, without substantially altering a Cas9 activity (e.g., cleavage activity), whereas changing an “essential” amino acid residue results in a substantial loss of activity (e.g., cleavage activity).

In an embodiment, a Cas9 molecule comprises a cleavage property that differs from naturally occurring Cas9 molecules, e.g., that differs from the naturally occurring Cas9 molecule having the closest homology. For example, a Cas9 molecule can differ from naturally occurring Cas9 molecules, e.g., a Cas9 molecule of S. aureus, S. pyogenes, or C. jejuni as follows: its ability to modulate, e.g., decreased or increased, cleavage of a double stranded break (endonuclease and/or exonuclease activity), e.g., as compared to a naturally occurring Cas9 molecule (e.g., a Cas9 molecule of S. aureus, S. pyogenes, or C. jejuni); its ability to modulate, e.g., decreased or increased, cleavage of a single strand of a nucleic acid, e.g., a non-complimentary strand of a nucleic acid molecule or a complementary strand of a nucleic acid molecule (nickase activity), e.g., as compared to a naturally occurring Cas9 molecule (e.g., a Cas9 molecule of S. aureus, S. pyogenes, or C. jejuni); or the ability to cleave a nucleic acid molecule, e.g., a double stranded or single stranded nucleic acid molecule, can be eliminated.

In an embodiment, the altered Cas9 molecule is an eaCas9 molecule comprising one or more of the following activities: cleavage activity associated with a RuvC domain; cleavage activity associated with an HNH domain; cleavage activity associated with an HNH domain and cleavage activity associated with a RuvC domain.

In an embodiment, the altered Cas9 molecule is an eiCas9 molecule which does not cleave a nucleic acid molecule (either double stranded or single stranded nucleic acid molecules) or cleaves a nucleic acid molecule with significantly less efficiency, e.g., less than 20, 10, 5, 1 or 0.1% of the cleavage activity of a reference Cas9 molecule, e.g., as measured by an assay described herein. The reference Cas9 molecule can be a naturally occurring unmodified Cas9 molecule, e.g., a naturally occurring Cas9 molecule such as a Cas9 molecule of S. pyogenes, S. thermophilus, S. aureus, C. jejuni or N. meningitidis. In an embodiment, the reference Cas9 molecule is the naturally occurring Cas9 molecule having the closest sequence identity or homology. In an embodiment, the eiCas9 molecule lacks substantial cleavage activity associated with a RuvC domain and cleavage activity associated with an HNH domain.

In an embodiment, the altered Cas9 molecule or Cas9 polypeptide is an eaCas9 molecule or eaCas9 polypeptide comprising the fixed amino acid residues of S. pyogenes shown in the consensus sequence disclosed in FIGS. 2A-2G, and has one or more amino acids that differ from the amino acid sequence of S. pyogenes (e.g., has a substitution) at one or more residue (e.g., 2, 3, 5, 10, 15, 20, 30, 50, 70, 80, 90, 100, 200 amino acid residues) represented by an “-” in the consensus sequence disclosed in FIGS. 2A-2G or SEQ ID NO: 7.

In an embodiment, the altered Cas9 molecule or Cas9 polypeptide comprises a sequence in which:

the sequence corresponding to the fixed sequence of the consensus sequence disclosed in FIGS. 2A-2G differs at no more than 1, 2, 3, 4, 5, 10, 15, or 20% of the fixed residues in the consensus sequence disclosed in FIGS. 2A-2G;

the sequence corresponding to the residues identified by “*” in the consensus sequence disclosed in FIGS. 2A-2G differ at no more than 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, or 40% of the “*” residues from the corresponding sequence of naturally occurring Cas9 molecule, e.g., an S. pyogenes Cas9 molecule; and,

the sequence corresponding to the residues identified by “-” in the consensus sequence disclosed in FIGS. 2A-2G differ at no more than 5, 10, 15, 20, 25, 30, 35, 40, 45, 55, or 60% of the “-” residues from the corresponding sequence of naturally occurring Cas9 molecule, e.g., an S. pyogenes Cas9 molecule.

In an embodiment, the altered Cas9 molecule or Cas9 polypeptide is an eaCas9 molecule or eaCas9 polypeptide comprising the fixed amino acid residues of S. thermophilus shown in the consensus sequence disclosed in FIGS. 2A-2G, and has one or more amino acids that differ from the amino acid sequence of S. thermophilus (e.g., has a substitution) at one or more residue (e.g., 2, 3, 5, 10, 15, 20, 30, 50, 70, 80, 90, 100, 200 amino acid residues) represented by an “-” in the consensus sequence disclosed in FIGS. 2A-2G. In an embodiment

In an embodiment, the altered Cas9 molecule or Cas9 polypeptide comprises a sequence in which:

the sequence corresponding to the fixed sequence of the consensus sequence disclosed in FIGS. 2A-2G differs at no more than 1, 2, 3, 4, 5, 10, 15, or 20% of the fixed residues in the consensus sequence disclosed in FIGS. 2A-2G;

the sequence corresponding to the residues identified by “*” in the consensus sequence disclosed in FIGS. 2A-2G differ at no more than 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, or 40% of the “*” residues from the corresponding sequence of naturally occurring Cas9 molecule, e.g., an S. thermophilus Cas9 molecule; and,

the sequence corresponding to the residues identified by “-” in the consensus sequence disclosed in FIGS. 2A-2G differ at no more than 5, 10, 15, 20, 25, 30, 35, 40, 45, 55, or 60% of the “-” residues from the corresponding sequence of naturally occurring Cas9 molecule, e.g., an S. thermophilus Cas9 molecule.

In an embodiment, the altered Cas9 molecule or Cas9 polypeptide is an eaCas9 molecule or eaCas9 polypeptide comprising the fixed amino acid residues of S. mutans shown in the consensus sequence disclosed in FIGS. 2A-2G, and has one or more amino acids that differ from the amino acid sequence of S. mutans (e.g., has a substitution) at one or more residue (e.g., 2, 3, 5, 10, 15, 20, 30, 50, 70, 80, 90, 100, 200 amino acid residues) represented by an “-” in the consensus sequence disclosed in FIGS. 2A-2G.

In an embodiment, the altered Cas9 molecule or Cas9 polypeptide comprises a sequence in which:

the sequence corresponding to the fixed sequence of the consensus sequence disclosed in FIGS. 2A-2G differs at no more than 1, 2, 3, 4, 5, 10, 15, or 20% of the fixed residues in the consensus sequence disclosed in FIGS. 2A-2G;

the sequence corresponding to the residues identified by “*” in the consensus sequence disclosed in FIGS. 2A-2G differ at no more than 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, or 40% of the “*” residues from the corresponding sequence of naturally occurring Cas9 molecule, e.g., an S. mutans Cas9 molecule; and,

the sequence corresponding to the residues identified by “-” in the consensus sequence disclosed in FIGS. 2A-2G differ at no more than 5, 10, 15, 20, 25, 30, 35, 40, 45, 55, or 60% of the “-” residues from the corresponding sequence of naturally occurring Cas9 molecule, e.g., an S. mutans Cas9 molecule.

In an embodiment, the altered Cas9 molecule or Cas9 polypeptide is an eaCas9 molecule or eaCas9 polypeptide comprising the fixed amino acid residues of L. innocula shown in the consensus sequence disclosed in FIGS. 2A-2G, and has one or more amino acids that differ from the amino acid sequence of L. innocula (e.g., has a substitution) at one or more residue (e.g., 2, 3, 5, 10, 15, 20, 30, 50, 70, 80, 90, 100, 200 amino acid residues) represented by an “-” in the consensus sequence disclosed in FIGS. 2A-2G.

In an embodiment, the altered Cas9 molecule or Cas9 polypeptide comprises a sequence in which:

the sequence corresponding to the fixed sequence of the consensus sequence disclosed in FIGS. 2A-2G differs at no more than 1, 2, 3, 4, 5, 10, 15, or 20% of the fixed residues in the consensus sequence disclosed in FIGS. 2A-2G;

the sequence corresponding to the residues identified by “*” in the consensus sequence disclosed in FIGS. 2A-2G differ at no more than 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, or 40% of the “*” residues from the corresponding sequence of naturally occurring Cas9 molecule, e.g., an L. innocula Cas9 molecule; and,

the sequence corresponding to the residues identified by “-” in the consensus sequence disclosed in FIGS. 2A-2G differ at no more than 5, 10, 15, 20, 25, 30, 35, 40, 45, 55, or 60% of the “-” residues from the corresponding sequence of naturally occurring Cas9 molecule, e.g., an L. innocula Cas9 molecule.

In an embodiment, the altered Cas9 molecule or Cas9 polypeptide, e.g., an eaCas9 molecule or eaCas9 polypeptide, can be a fusion, e.g., of two of more different Cas9 molecules, e.g., of two or more naturally occurring Cas9 molecules of different species. For example, a fragment of a naturally occurring Cas9 molecule of one species can be fused to a fragment of a Cas9 molecule of a second species. As an example, a fragment of a Cas9 molecule of S. pyogenes comprising an N-terminal RuvC-like domain can be fused to a fragment of Cas9 molecule of a species other than S. pyogenes (e.g., S. thermophilus) comprising an HNH-like domain.

Cas9 Molecules and Cas9 Polypeptides with Altered PAM Recognition or No PAM Recognition

Naturally occurring Cas9 molecules can recognize specific PAM sequences, for example the PAM recognition sequences described above for, e.g., S. pyogenes, S. thermophilus, S. mutans, S. aureus and N. meningitidis.

In an embodiment, a Cas9 molecule or Cas9 polypeptide has the same PAM specificities as a naturally occurring Cas9 molecule. In an embodiment, a Cas9 molecule or Cas9 polypeptide has a PAM specificity not associated with a naturally occurring Cas9 molecule, or a PAM specificity not associated with the naturally occurring Cas9 molecule to which it has the closest sequence homology. For example, a naturally occurring Cas9 molecule can be altered, e.g., to alter PAM recognition, e.g., to alter the PAM sequence that the Cas9 molecule or Cas9 polypeptide recognizes to decrease off target sites and/or improve specificity; or eliminate a PAM recognition requirement. In an embodiment, a Cas9 molecule or Cas9 polypeptide can be altered, e.g., to increase length of PAM recognition sequence and/or improve Cas9 specificity to high level of identity (e.g., 98%, 99% or 100% match between gRNA and a PAM sequence), e.g., to decrease off target sites and increase specificity. In an embodiment, the length of the PAM recognition sequence is at least 4, 5, 6, 7, 8, 9, 10 or 15 amino acids in length. In an embodiment, the Cas9 specificity requires at least 90%, 95%, 96%, 97%, 98%, 99% or more homology between the gRNA and the PAM sequence. Cas9 molecules or Cas9 polypeptides that recognize different PAM sequences and/or have reduced off-target activity can be generated using directed evolution. Exemplary methods and systems that can be used for directed evolution of Cas9 molecules are described, e.g., in Esvelt et al. Nature 2011, 472(7344): 499-503. Candidate Cas9 molecules can be evaluated, e.g., by methods described in Section IV.

Alterations of the PI domain, which mediates PAM recognition are discussed below.

Synthetic Cas9 Molecules and Cas9 Polypeptides with Altered PI Domains

Current genome-editing methods are limited in the diversity of target sequences that can be targeted by the PAM sequence that is recognized by the Cas9 molecule utilized. A synthetic Cas9 molecule (or Syn-Cas9 molecule), or synthetic Cas9 polypeptide (or syn-Cas9 polypeptide), as that term is used herein, refers to a Cas9 molecule or Cas9 polypeptide that comprises a Cas9 core domain from one bacterial species and a functional altered PI domain, i.e., a PI domain other than that naturally associated with the Cas9 core domain, e.g., from a different bacterial species.

In an embodiment, the altered PI domain recognizes a PAM sequence that is different from the PAM sequence recognized by the naturally-occurring Cas9 from which the Cas9 core domain is derived. In an embodiment, the altered PI domain recognizes the same PAM sequence recognized by the naturally-occurring Cas9 from which the Cas9 core domain is derived, but with different affinity or specificity. A Syn-Cas9 molecule or Syn-Cas9 polypetide can be, respectively, a Syn-eaCas9 molecule or Syn-eaCas9 polypeptide or a Syn-eiCas9 molecule Syn-eiCas9 polypeptide.

An exemplary Syn-Cas9 molecule Syn-Cas9 polypetide comprises:

a) a Cas9 core domain, e.g., a Cas9 core domain from Table 28 or 29, e.g., a S. aureus, S. pyogenes, or C. jejuni Cas9 core domain; and

b) an altered PI domain from a species X Cas9 sequence selected from Tables 31 and 32.

In an embodiment, the RKR motif (the PAM binding motif) of said altered PI domain comprises: differences at 1, 2, or 3 amino acid residues; a difference in amino acid sequence at the first, second, or third position; differences in amino acid sequence at the first and second positions, the first and third positions, or the second and third positions; as compared with the sequence of the RKR motif of the native or endogenous PI domain associated with the Cas9 core domain.

In an embodiment, the Cas9 core domain comprises the Cas9 core domain from a species X Cas9 from Table 28 and said altered PI domain comprises a PI domain from a species Y Cas9 from Table 28.

In an embodiment, the RKR motif of the species X Cas9 is other than the RKR motif of the species Y Cas9.

In an embodiment, the RKR motif of the altered PI domain is selected from XXY, XNG, and XNQ.

In an embodiment, the altered PI domain has at least 60, 70, 80, 90, 95, or 100% homology with the amino acid sequence of a naturally occurring PI domain of said species Y from Table 28.

In an embodiment, the altered PI domain differs by no more than 50, 40, 30, 25, 20, 15, 10, 5, 4, 3, 2, or 1 amino acid residue from the amino acid sequence of a naturally occurring PI domain of said second species from Table 28.

In an embodiment, the Cas9 core domain comprises a S. aureus core domain and altered PI domain comprises: an A. denitrificans PI domain; a C. jejuni PI domain; a H. mustelae PI domain; or an altered PI domain of species X PI domain, wherein species X is selected from Table 32.

In an embodiment, the Cas9 core domain comprises a S. pyogenes core domain and the altered PI domain comprises: an A. denitrificans PI domain; a C. jejuni PI domain; a H. mustelae PI domain; or an altered PI domain of species X PI domain, wherein species X is selected from Table 32.

In an embodiment, the Cas9 core domain comprises a C. jejuni core domain and the altered PI domain comprises: an A. denitrificans PI domain; a H. mustelae PI domain; or an altered PI domain of species X PI domain, wherein species X is selected from Table 32.

In an embodiment, the Cas9 molecule further comprises a linker disposed between said Cas9 core domain and said altered PI domain.

In an embodiment, the linker comprises: a linker described elsewhere herein disposed between the Cas9 core domain and the heterologous PI domain. Suitable linkers are further described in Section V.

Exemplary altered PI domains for use in Syn-Cas9 molecules are described in Tables 31 and 32. The sequences for the 83 Cas9 orthologs referenced in Tables 31 and 32 are provided in Table 28. Table 30 provides the Cas9 orthologs with known PAM sequences and the corresponding RKR motif.

In an embodiment, a Syn-Cas9 molecule may also be size-optimized, e.g., the Syn-Cas9 molecule comprises one or more deletions, and optionally one or more linkers disposed between the amino acid residues flanking the deletions. In an embodiment, a Syn-Cas9 molecule comprises a REC deletion.

Size-Optimized Cas9 Molecules

Engineered Cas9 molecules and engineered Cas9 polypeptides described herein include a Cas9 molecule or Cas9 polypeptide comprising a deletion that reduces the size of the molecule while still retaining desired Cas9 properties, e.g., essentially native conformation, Cas9 nuclease activity, and/or target nucleic acid molecule recognition. Provided herein are Cas9 molecules or Cas9 polypeptides comprising one or more deletions and optionally one or more linkers, wherein a linker is disposed between the amino acid residues that flank the deletion. Methods for identifying suitable deletions in a reference Cas9 molecule, methods for generating Cas9 molecules with a deletion and a linker, and methods for using such Cas9 molecules will be apparent to one of ordinary skill in the art upon review of this document.

A Cas9 molecule, e.g., a S. aureus, S. pyogenes, or C. jejuni, Cas9 molecule, having a deletion is smaller, e.g., has reduced number of amino acids, than the corresponding naturally-occurring Cas9 molecule. The smaller size of the Cas9 molecules allows increased flexibility for delivery methods, and thereby increases utility for genome-editing. A Cas9 molecule can comprise one or more deletions that do not substantially affect or decrease the activity of the resultant Cas9 molecules described herein. Activities that are retained in the Cas9 molecules comprising a deletion as described herein include one or more of the following:

a nickase activity, i.e., the ability to cleave a single strand, e.g., the non-complementary strand or the complementary strand, of a nucleic acid molecule; a double stranded nuclease activity, i.e., the ability to cleave both strands of a double stranded nucleic acid and create a double stranded break, which in an embodiment is the presence of two nickase activities; an endonuclease activity;

an exonuclease activity;

a helicase activity, i.e., the ability to unwind the helical structure of a double stranded nucleic acid;

and recognition activity of a nucleic acid molecule, e.g., a target nucleic acid or a gRNA.

Activity of the Cas9 molecules described herein can be assessed using the activity assays described herein or in the art.

Identifying Regions Suitable for Deletion

Suitable regions of Cas9 molecules for deletion can be identified by a variety of methods. Naturally-occurring orthologous Cas9 molecules from various bacterial species, e.g., any one of those listed in Table 28, can be modeled onto the crystal structure of S. pyogenes Cas9 (Nishimasu et al., Cell, 156:935-949, 2014) to examine the level of conservation across the selected Cas9 orthologs with respect to the three-dimensional conformation of the protein. Less conserved or unconserved regions that are spatially located distant from regions involved in Cas9 activity, e.g., interface with the target nucleic acid molecule and/or gRNA, represent regions or domains are candidates for deletion without substantially affecting or decreasing Cas9 activity.

REC-Optimized Cas9 Molecules

A REC-optimized Cas9 molecule, as that term is used herein, refers to a Cas9 molecule that comprises a deletion in one or both of the REC2 domain and the RE1_(CT) domain (collectively a REC deletion), wherein the deletion comprises at least 10% of the amino acid residues in the cognate domain. A REC-optimized Cas9 molecule can be an eaCas9 molecule or an eiCas9 molecule. An exemplary REC-optimizedCas9 molecule comprises:

a) a deletion selected from:

-   -   i) a REC2 deletion;     -   ii) a REC1_(CT) deletion; or     -   iii) a REC1_(SUB) deletion.

Optionally, a linker is disposed between the amino acid residues that flank the deletion. In an embodiment a Cas9 molecule includes only one deletion, or only two deletions. A Cas9 molecule can comprise a REC2 deletion and a REC1C_(T) deletion. A Cas9 molecule can comprise a REC2 deletion and a REC1_(SUB) deletion.

Generally, the deletion will contain at least 10% of the amino acids in the cognate domain, e.g., a REC2 deletion will include at least 10% of the amino acids in the REC2 domain.

A deletion can comprise: at least 10, 20, 30, 40, 50, 60, 70, 80, or 90% of the amino acid residues of its cognate domain; all of the amino acid residues of its cognate domain; an amino acid residue outside its cognate domain; a plurality of amino acid residues outside its cognate domain; the amino acid residue immediately N terminal to its cognate domain; the amino acid residue immediately C terminal to its cognate domain; the amino acid residue immediately N terminal to its cognate and the amino acid residue immediately C terminal to its cognate domain; a plurality of, e.g., up to 5, 10, 15, or 20, amino acid residues N terminal to its cognate domain; a plurality of, e.g., up to 5, 10, 15, or 20, amino acid residues C terminal to its cognate domain; a plurality of, e.g., up to 5, 10, 15, or 20, amino acid residues N terminal to its cognate domain and a plurality of e.g., up to 5, 10, 15, or 20, amino acid residues C terminal to its cognate domain.

In an embodiment, a deletion does not extend beyond: its cognate domain; the N terminal amino acid residue of its cognate domain; the C terminal amino acid residue of its cognate domain.

A REC-optimized Cas9 molecule can include a linker disposed between the amino acid residues that flank the deletion. Suitable linkers for use between the amino acid resides that flank a REC deletion in a REC-optimized Cas9 molecule is disclosed in Section V.

In an embodiment a REC-optimized Cas9 molecule comprises an amino acid sequence that, other than any REC deletion and associated linker, has at least 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 99, or 100% homology with the amino acid sequence of a naturally occurring Cas 9, e.g., a Cas9 molecule described in Table 28, e.g., a S. aureus Cas9 molecule, a S. pyogenes Cas9 molecule, or a C. jejuni Cas9 molecule.

In an embodiment, a REC-optimized Cas9 molecule comprises an amino acid sequence that, other than any REC deletion and associated linker, differs by no more than 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, or 25, amino acid residues from the amino acid sequence of a naturally occurring Cas 9, e.g., a Cas9 molecule described in Table 28, e.g., a S. aureus Cas9 molecule, a S. pyogenes Cas9 molecule, or a C. jejuni Cas9 molecule.

In an embodiment, a REC-optimized Cas9 molecule comprises an amino acid sequence that, other than any REC deletion and associate linker, differs by no more than 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, or 25% of the, amino acid residues from the amino acid sequence of a naturally occurring Cas 9, e.g., a Cas9 molecule described in Table 28, e.g., a S. aureus Cas9 molecule, a S. pyogenes Cas9 molecule, or a C. jejuni Cas9 molecule.

For sequence comparison, typically one sequence acts as a reference sequence, to which test sequences are compared. When using a sequence comparison algorithm, test and reference sequences are entered into a computer, subsequence coordinates are designated, if necessary, and sequence algorithm program parameters are designated. Default program parameters can be used, or alternative parameters can be designated. The sequence comparison algorithm then calculates the percent sequence identities for the test sequences relative to the reference sequence, based on the program parameters. Methods of alignment of sequences for comparison are well known in the art. Optimal alignment of sequences for comparison can be conducted, e.g., by the local homology algorithm of Smith and Waterman, (1970) Adv. Appl. Math. 2:482c, by the homology alignment algorithm of Needleman and Wunsch, (1970) J. Mol. Biol. 48:443, by the search for similarity method of Pearson and Lipman, (1988) Proc. Nat'l. Acad. Sci. USA 85:2444, by computerized implementations of these algorithms (GAP, BESTFIT, FASTA, and TFASTA in the Wisconsin Genetics Software Package, Genetics Computer Group, 575 Science Dr., Madison, Wis.), or by manual alignment and visual inspection (see, e.g., Brent et al., (2003) Current Protocols in Molecular Biology).

Two examples of algorithms that are suitable for determining percent sequence identity and sequence similarity are the BLAST and BLAST 2.0 algorithms, which are described in Altschul et al., (1977) Nuc. Acids Res. 25:3389-3402; and Altschul et al., (1990) J. Mol. Biol. 215:403-410, respectively. Software for performing BLAST analyses is publicly available through the National Center for Biotechnology Information.

The percent identity between two amino acid sequences can also be determined using the algorithm of E. Meyers and W. Miller, (1988) Comput. Appl. Biosci. 4:11-17) which has been incorporated into the ALIGN program (version 2.0), using a PAM120 weight residue table, a gap length penalty of 12 and a gap penalty of 4. In addition, the percent identity between two amino acid sequences can be determined using the Needleman and Wunsch (1970) J. Mol. Biol. 48:444-453) algorithm which has been incorporated into the GAP program in the GCG software package (available at www.gcg.com), using either a Blossom 62 matrix or a PAM250 matrix, and a gap weight of 16, 14, 12, 10, 8, 6, or 4 and a length weight of 1, 2, 3, 4, 5, or 6.

Sequence information for exemplary REC deletions are provided for 83 naturally-occurring Cas9 orthologs in Table 28.

The amino acid sequences of exemplary Cas9 molecules from different bacterial species are shown below.

TABLE 28 Amino Add Sequence of Cas9 Orthologs REC2 REC1_(CT) Rec_(sub) start stop start stop start stop Amino acid (AA (AA # AA (AA (AA # AA (AA (AA # AA Species/Composite ID sequence pos) pos) deleted (n) pos) pos) deleted (n) pos) pos) deleted (n) Staphylococcus Aureus SEQ ID NO: 126 166 41 296 352 57 296 352 57 tr|J7RUA5|J7RUA5_STAAU 304 Streptococcus Pyogenes SEQ ID NO: 176 314 139 511 592 82 511 592 82 sp|Q99ZW2|CAS9_STRP1 305 Campylobacter jejuni NCTC SEQ ID NO: 137 181 45 316 360 45 316 360 45 11168 306 gi|218563121|ref|YP_002344900.1 Bacteroides fragilis NCTC 9343 SEQ ID NO: 148 339 192 524 617 84 524 617 84 gi|60683389|ref|YP_213533.1| 307 Bifidobacterium bifidum S17 SEQ ID NO: 173 335 163 516 607 87 516 607 87 gi|310286728|ref|YP_003937986. 308 Veillonella atypica ACS-134-V- SEQ ID NO: 185 339 155 574 663 79 574 663 79 Col7a 309 gi|303229466|ref|ZP_07316256.1 Lactobacillus rhamnosus GG SEQ ID NO: 169 320 152 559 645 78 559 645 78 gi|258509199|ref|YP_003171950.1 310 Filifactor alocis ATCC 35896 SEQ ID NO: 166 314 149 508 592 76 508 592 76 gi|374307738|ref|YP_005054169.1 311 Oenococcus kitaharae DSM SEQ ID NO: 169 317 149 555 639 80 555 639 80 17330 312 gi|366983953|gb|EHN59352.1| Fructobacillus fructosus KCTC SEQ ID NO: 168 314 147 488 571 76 488 571 76 3544 313 gi|339625081|ref|ZP_08660870.1 Catenibacterium mitsuokai DSM SEQ ID NO: 173 318 146 511 594 78 511 594 78 15897 314 gi|224543312|ref|ZP_03683851.1 Finegoldia magna ATCC 29328 SEQ ID NO: 168 313 146 452 534 77 452 534 77 gi|169823755|ref|YP_001691366.1 315 Coriobacterium glomerans PW2 SEQ ID NO: 175 318 144 511 592 82 511 592 82 gi|328956315|ref|YP_004373648.1 316 Eubacterium yurii ATCC 43715 SEQ ID NO: 169 310 142 552 633 76 552 633 76 gi|306821691|ref|ZP_07455288.1 317 Peptoniphilus duerdenii ATCC SEQ ID NO: 171 311 141 535 615 76 535 615 76 BAA-1640 318 gi|304438954|ref|ZP_07398877.1 Acidaminococcus sp. D21 SEQ ID NO: 167 306 140 511 591 75 511 591 75 gi|227824983|ref|ZP_03989815.1 319 Lactobacillus farciminis KCTC SEQ ID NO: 171 310 140 542 621 85 542 621 85 3681 320 gi|336394882|ref|ZP_08576281.1 Streptococcus sanguinis SK49 SEQ ID NO: 185 324 140 411 490 85 411 490 85 gi|422884106|ref|ZP_16930555.1 321 Coprococcus catus GD-7 SEQ ID NO: 172 310 139 556 634 76 556 634 76 gi|291520705|emb|CBK78998.11 322 Streptococcus mutans UA159 SEQ ID NO: 176 314 139 392 470 84 392 470 84 gi|24379809|ref|NP_721764.1| 323 Streptococcus pyogenes M1 GAS SEQ ID NO: 176 314 139 523 600 82 523 600 82 gi|13622193|gb|AAK33936.1| 324 Streptococcus thermophilus SEQ ID NO: 176 314 139 481 558 81 481 558 81 LMD-9 325 gi|116628213|ref|YP_820832.1| Fusobacterium nucleatum SEQ ID NO: 171 308 138 537 614 76 537 614 76 ATCC49256 326 gi|34762592|ref|ZP_00143587.1| Pianococcus antarcticus DSM SEQ ID NO: 162 299 138 538 614 94 538 614 94 14505 327 gi|389815359|ref|ZP_10206685.1 Treponema denticola ATCC SEQ ID NO: 169 305 137 524 600 81 524 600 81 35405 328 gi|42525843|ref|NP_970941.1| Solobacterium moorei F0204 SEQ ID NO: 179 314 136 544 619 77 544 619 77 gi|320528778|ref|ZP_08029929.1 329 Staphylococcus SEQ ID NO: 164 299 136 531 606 92 531 606 92 pseudintermedius ED99 330 gb|323463801|gb|ADX75954.1| Flavobacterium branchiophilum SEQ ID NO: 162 286 125 538 613 63 538 613 63 FL-15 331 gi|347536497|ref|YP_004843922.1 Ignavibacterium album JCM SEQ ID NO: 223 329 107 357 432 90 357 432 90 16511 332 gi|385811609|ref|YP_005848005.1 Bergeyella zoohelcum ATCC SEQ ID NO: 165 261 97 529 604 56 529 604 56 43767 333 gi|423317190|ref|ZP_17295095.1 Nitrobacter hamburgensis X14 SEQ ID NO: 169 253 85 536 611 48 536 611 48 gi|92109262|ref|YP_571550.1| 334 Odoribacter laneus YIT 12061 SEQ ID NO: 164 242 79 535 610 63 535 610 63 gi|374384763|ref|ZP_09642280.1 335 Legionella pneumophila str. SEQ ID NO: 164 239 76 402 476 67 402 476 67 Paris 336 gi|54296138|ref|YP_122507.1| Bacteroides sp. 20 3 SEQ ID NO: 198 269 72 530 604 83 530 604 83 gi|301311869|ref|ZP_07217791.1 337 Akkermansia muciniphila ATCC SEQ ID NO: 136 202 67 348 418 62 348 418 62 BAA-835 338 gi|187736489|ref|YP_001878601 Prevotella sp. C561 SEQ ID NO: 184 250 67 357 425 78 357 425 78 gi|345885718|ref|ZP_08837074.1 339 Wolinella succinogenes DSM SEQ ID NO: 157 218 36 401 468 60 401 468 60 1740 340 gi|34557932|ref|NP_907747.1| Alicyclobacillus hesperidum SEQ ID NO: 142 196 55 416 482 61 416 482 61 URH17-3-68 341 gi|403744858|ref|ZP_10953934.1 Caenispirillum salinarum AK4 SEQ ID NO: 161 214 54 330 393 68 330 393 68 gi|427429481|ref|ZP_18919511.1 342 Eubacterium rectale ATCC SEQ ID NO: 133 185 53 322 384 60 322 384 60 33656 343 gi|238924075|ref|YP_002937591.1 Mycoplasma synoviae 53 SEQ ID NO: 187 239 53 319 381 80 319 381 80 gi|71894592|ref|YP_278700.1| 344 Porphyromonas sp. oral taxon SEQ ID NO: 150 202 53 309 371 60 309 371 60 279 str. F0450 345 gi|402847315|ref|ZP_10895610.1 Streptococcus thermophilus SEQ ID NO: 127 178 139 424 486 81 424 486 81 LMD-9 346 gi|116627542|ref|YP_820161.1| Roseburia inulinivorans DSM SEQ ID NO: 154 204 51 318 380 69 318 380 69 16841 347 gi|225377804|ref|ZP_03755025.1 Methylosinus trichosporium SEQ ID NO: 144 193 50 426 488 64 426 488 64 OB3b 348 gi|296446027|ref|ZP_06887976.1 Ruminococcus albus 8 SEQ ID NO: 139 187 49 351 412 55 351 412 55 gi|325677756|ref|ZP_08157403.1 349 Bifidobacterium longum SEQ ID NO: 183 230 48 370 431 44 370 431 44 DJO10A 350 gi|189440764|ref|YP_001955845 Enterococcus faecalis TX0012 SEQ ID NO: 123 170 48 327 387 60 327 387 60 gi|315149830|gb|EFT93846.1| 351 Mycoplasma mobile 163K SEQ ID NO: 179 226 48 314 374 79 314 374 79 gi|47458868|ref|YP_015730.1| 352 Actinomyces coleocanis DSM SEQ ID NO: 147 193 47 358 418 40 358 418 40 15436 353 gi|227494853|ref|ZP_03925169.1 Dinoroseobacter shibae DFL 12 SEQ ID NO: 138 184 47 338 398 48 338 398 48 gi|159042956|ref|YP_001531750.1 354 Actinomyces sp. oral taxon 180 SEQ ID NO: 183 228 46 349 409 40 349 409 40 str. F0310 355 gi|315605738|ref|ZP_07880770.1 Alcanivorax sp. W11-5 SEQ ID NO: 139 183 45 344 404 61 344 404 61 gi|407803669|ref|ZP_11150502.1 356 Aminomonas paucivorans DSM SEQ ID NO: 134 178 45 341 401 63 341 401 63 12260 357 gi|312879015|ref|ZP_07738815.1 Mycoplasma cams PG 14 SEQ ID NO: 139 183 45 319 379 76 319 379 76 gi|384393286|gb|EIE39736.1| 358 Lactobacillus coryniformis SEQ ID NO: 141 184 44 328 387 61 328 387 61 KCTC 3535 359 gi|336393381|ref|ZP_08574780.1 Elusimicrobium minutum Pei191 SEQ ID NO: 177 219 43 322 381 47 322 381 47 gi|187250660|ref|YP_001875142.1 360 Neisseria meningitidis Z2491 SEQ ID NO: 147 189 43 360 419 61 360 419 61 gi|218767588|ref|YP_002342100.1 361 Pasteurella multocida str. Pm70 SEQ ID NO: 139 181 43 319 378 61 319 378 61 gi|15602992|ref|NP_246064.1| 362 Rhodovulum sp. PH10 SEQ ID NO: 141 183 43 319 378 48 319 378 48 gi|402849997|ref|ZP_10898214.1 363 Eubacterium dolichum DSM SEQ ID NO: 131 172 42 303 361 59 303 361 59 3991 364 gi|160915782|ref|ZP_02077990.1 Nitratifractor salsuginis DSM SEQ ID NO: 143 184 42 347 404 61 347 404 61 16511 365 gi|319957206|ref|YP_004168469.1 Rhodospirillum rubrum ATCC SEQ ID NO: 139 180 42 314 371 55 314 371 55 11170 366 gi|83591793|ref|YP_425545.1| Clostridium cellulolyticum H10 SEQ ID NO: 137 176 40 320 376 61 320 376 61 gi|220930482|ref|YP_002507391.1 367 Helicobacter mustelae 12198 SEQ ID NO: 148 187 40 298 354 48 298 354 48 gi|291276265|ref|YP_003516037.1 368 Ilyobacter polytropus DSM 2926 SEQ ID NO: 134 173 40 462 517 63 462 517 63 gi|310780384|ref|YP_003968716.1 369 Sphaerochaeta globus str. Buddy SEQ ID NO: 163 202 40 335 389 45 335 389 45 gi|325972003|ref|YP_004248194.1 370 Staphylococcus lugdunensis SEQ ID NO: 128 167 40 337 391 57 337 391 57 M23590 371 gi|315659848|ref|ZP_07912707.1 Treponema sp. JC4 SEQ ID NO: 144 183 40 328 382 63 328 382 63 gi|384109266|ref|ZP_10010146.1 372 uncultured delta proteobacterium SEQ ID NO: 154 193 40 313 365 55 313 365 55 HF0070 07E19 373 gi|297182908|gb|ADI19058.1| Alicycliphilus denitrificans K601 SEQ ID NO: 140 178 39 317 366 48 317 366 48 gi|330822845|ref|YP_004386148.1 374 Azospirillum sp. B510 SEQ ID NO: 205 243 39 342 389 46 342 389 46 gi|288957741|ref|YP_003448082.1 375 Bradyrhizobium sp. BTAi1 SEQ ID NO: 143 181 39 323 370 48 323 370 48 gi|148255343|ref|YP_001239928.1 376 Parvibaculum lavamentivorans SEQ ID NO: 138 176 39 327 374 58 327 374 58 DS-1 377 gi|154250555|ref|YP_001411379.1 Prevotella timonensis CRIS 5C- SEQ ID NO: 170 208 39 328 375 61 328 375 61 B1 378 gi|282880052|ref|ZP_06288774.1 Bacillus smithii 7 3 47FAA SEQ ID NO: 134 171 38 401 448 63 401 448 63 gi|365156657|ref|ZP_09352959.1 379 Cand. Puniceispirillum marinum SEQ ID NO: 135 172 38 344 391 53 344 391 53 IMCC1322 380 gi|294086111|ref|YP_003552871.1 Barnesiella intestinihominis YIT SEQ ID NO: 140 176 37 371 417 60 371 417 60 11860 381 gi|404487228|ref|ZP_11022414.1 Ralstonia syzygii R24 SEQ ID NO: 140 176 37 395 440 50 395 440 50 gi|344171927|emb|CCA84553.1| 382 Wolinella succinogenes DSM SEQ ID NO: 145 180 36 348 392 60 348 392 60 1740 383 gi|34557790|ref|NP_907605.1| Mycoplasma gallisepticumstr. F SEQ ID NO: 144 177 34 373 416 71 373 416 71 gi|284931710|gb|ADC31648.1| 384 Acidothermus cellulolyticus 11B SEQ ID NO: 150 182 33 341 380 58 341 380 58 gi|117929158|ref|YP_873709.1| 385 Mycoplasma ovipneumoniae SEQ ID NO: 156 184 29 381 420 62 381 420 62 SC01 386 gi|363542550|ref|ZP_09312133.1

TABLE 29 Amino Acid Sequence of Cas9 Core Domains Cas9 Start (AA Cas9 Stop (AA Strain Name pos) pos) Start and Stop numbers refer to the sequence in Table 28 Staphylococcus Aureus 1 772 Streptococcus Pyogenes 1 1099 Campulobacter Jejuni 1 741

TABLE 30 Identified PAM sequences and corresponding RKR motifs. PAM sequence RKR motif Strain Name (NA) (AA) Streptococcus pyogenes NGG RKR Streptococcus mutans NGG RKR Streptococcus thermophilus A NGGNG RYR Treponema denticola NAAAAN VAK Streptococcus thermophilus B NNAAAAW IYK Campylobacter jejuni NNNNACA NLK Pasteurella multocida GNNNCNNA KDG Neisseria meningitidis NNNNGATT or IGK Staphylococcus aureus NNGRRV (R = A or G; V = A. G NDK or C) NNGRRT (R = A or G) PI domains are provided in Tables 31 and 32.

TABLE 31 Altered PI Domains PI Start PI Stop (AA Length of RKR Strain Name (AA pos) pos) PI (AA) motif (AA) Start and Stop numbers refer to the sequences in Table 28 Alicycliphilus denitrificans K601 837 1029 193 --Y Campylobacter jejuni NCTC 11168 741 984 244 -NG Helicobacter mustelae 12198 771 1024 254 -NQ

TABLE 32 Other Altered PI Domains PI Start PI Stop Length RKR (AA (AA of PI motif Strain Name pos) pos) (AA) (AA) Start and Stop numbers refer to the sequences in Table 28 Akkermansia muciniphila ATCC BAA-835 871 1101 231 ALK Ralstonia syzygii R24 821 1062 242 APY Cand. Puniceispirillum marinum IMCC1322 815 1035 221 AYK Fructobacillus fructosus KCTC 3544 1074 1323 250 DGN Eubacterium yurii ATCC 43715 1107 1391 285 DGY Eubacterium dolichum DSM 3991 779 1096 318 DKK Dinoroseobacter shibae DFL 12 851 1079 229 DPI Clostridium cellulolyticum H10 767 1021 255 EGK Pasteurella multocida str. Pm70 815 1056 242 ENN Mycoplasma canis PG 14 907 1233 327 EPK Porphyromonas sp. oral taxon 279 str. F0450 935 1197 263 EPT Filifactor alocis ATCC 35896 1094 1365 272 EVD Aminomonas paucivorans DSM 12260 801 1052 252 EVY Wolinella succinogenes DSM 1740 1034 1409 376 EYK Oenococcus kitaharae DSM 17330 1119 1389 271 GAL CoriobacteriumglomeransPW2 1126 1384 259 GDR Peptoniphilus duerdenii ATCC BAA-1640 1091 1364 274 GDS Bifidobacterium bifidum S17 1138 1420 283 GGL Alicyclobacillus hesperidum URH17-3-68 876 1146 271 GGR Roseburia inulinivorans DSM 16841 895 1152 258 GGT Actinomyces coleocanis DSM 15436 843 1105 263 GKK Odoribacter laneus YIT 12061 1103 1498 396 GKV Coprococcus catus GD-7 1063 1338 276 GNQ Enterococcus faecalis TX0012 829 1150 322 GRK Bacillus smithii 7 3 47FAA 809 1088 280 GSK Legionella pneumophila str. Paris 1021 1372 352 GTM Bacteroides fragilis NCTC 9343 1140 1436 297 IPV Mycoplasma ovipneumoniae SC01 923 1265 343 IRI Actinomyces sp. oral taxon 180 str. F0310 895 1181 287 KEK Treponema sp. JC4 832 1062 231 KIS Fusobacteriumnucleatum ATCC49256 1073 1374 302 KKV Lactobacillus farciminis KCTC 3681 1101 1356 256 KKV Nitratifractor salsuginis DSM 16511 840 1132 293 KMR Lactobacillus coryniformis KCTC 3535 850 1119 270 KNK Mycoplasma mobile 163K 916 1236 321 KNY Flavobacterium branchiophilum FL-15 1182 1473 292 KQK Prevotella timonensis CRIS 5C-B1 957 1218 262 KQQ Methylosinus trichosporium OB3b 830 1082 253 KRP Prevotella sp. C561 1099 1424 326 KRY Mycoplasma gallisepticum str. F 911 1269 359 KTA Lactobacillus rhamnosus GG 1077 1363 287 KYG Wolinella succinogenes DSM 1740 811 1059 249 LPN Streptococcus thermophilus LMD-9 1099 1388 290 MLA Treponema denticola ATCC 35405 1092 1395 304 NDS Bergeyella zoohelcum ATCC 43767 1098 1415 318 NEK Veillonella atypica ACS-134-V-Col7a 1107 1398 292 NGF Neisseria meningitidis Z2491 835 1082 248 NHN Ignavibacterium album JCM 16511 1296 1688 393 NKK Ruminococcus albus 8 853 1156 304 NNF Streptococcus thermophilus LMD-9 811 1121 311 NNK Barnesiella intestinihominis YIT 11860 871 1153 283 NPV Azospirillum sp. B510 911 1168 258 PFH Rhodospirillum rubrum ATCC 11170 863 1173 311 PRG Pianococcus antarcticus DSM 14505 1087 1333 247 PYY Staphylococcus pseudintermedius ED99 1073 1334 262 QIV Alcanivorax sp. W11-5 843 1113 271 RIE Bradyrhizobium sp. BTAi1 811 1064 254 RIY Streptococcus pyogenes M1 GAS 1099 1368 270 RKR Streptococcus mutans UA159 1078 1345 268 RKR Streptococcus Pyogenes 1099 1368 270 RKR Bacteroides sp. 20 3 1147 1517 371 RNI S. aureus 772 1053 282 RNK Solobacterium moorei F0204 1062 1327 266 RSG Finegoldia magna ATCC 29328 1081 1348 268 RTE uncultured delta proteobacterium HF0070 07E19 770 1011 242 SGG Acidaminococcus sp. D21 1064 1358 295 SIG Eubacterium rectale ATCC 33656 824 1114 291 SKK Caenispirillum salinarum AK4 1048 1442 395 SLV Acidothermus cellulolyticus 11B 830 1138 309 SPS Catenibacterium mitsuokai DSM 15897 1068 1329 262 SPT Parvibaculum lavamentivorans DS-1 827 1037 211 TGN Staphylococcus lugdunensis M23590 772 1054 283 TKK Streptococcus sanguinis SK49 1123 1421 299 TRM Elusimicrobium minutum Pei191 910 1195 286 TTG Nitrobacter hamburgensis X14 914 1166 253 VAY Mycoplasma synoviae 53 991 1314 324 VGF Sphaerochaeta globus str. Buddy 877 1179 303 VKG Ilyobacter polytropus DSM 2926 837 1092 256 VNG Rhodovulum sp. PH 10 821 1059 239 VPY Bifidobacterium longum DJO10A 904 1187 284 VRK

Amino acid sequences described in Table 28: SEQ ID NO: 304 MKRNYILGLDIGITSVGYGIIDYETRDVIDAGVRLFKEANVENNEGRRSKRGARRLKRRRRHRI QRVKKLLFDYNLLTDHSELSGINPYEARVKGLSQKLSEEEFSAALLHLAKRRGVHNVNEVEEDT GNELSTKEQISRNSKALEEKYVAELQLERLKKDGEVRGSINRFKTSDYVKEAKQLLKVQKAYHQ LDQSFIDTYIDLLETRRTYYEGPGEGSPFGWKDIKEWYEMLMGHCTYFPEELRSVKYAYNADLY NALNDLNNLVITRDENEKLEYYEKFQIIENVFKQKKKPTLKQIAKEILVNEEDIKGYRVTSTGK PEFTNLKVYHDIKDITARKEIIENAELLDQIAKILTIYQSSEDIQEELTNLNSELTQEEIEQIS NLKGYTGTHNLSLKAINLILDELWHTNDNQIAIFNRLKLVPKKVDLSQQKEIPTTLVDDFILSP VVKRSFIQSIKVINAIIKKYGLPNDIIIELAREKNSKDAQKMINEMQKRNRQTNERIEEIIRTT GKENAKYLIEKIKLHDMQEGKCLYSLEAIPLEDLLNNPFNYEVDHIIPRSVSFDNSFNNKVLVK QEENSKKGNRTPFQYLSSSDSKISYETFKKHILNLAKGKGRISKTKKEYLLEERDINRFSVQKD FINRNLVDTRYATRGLMNLLRSYFRVNNLDVKVKSINGGFTSFLRRKWKFKKERNKGYKHHAED ALIIANADFIFKEWKKLDKAKKVMENQMFEEKQAESMPEIETEQEYKEIFITPHQIKHIKDFKD YKYSHRVDKKPNRELINDTLYSTRKDDKGNTLIVNNLNGLYDKDNDKLKKLINKSPEKLLMYHH DPQTYQKLKLIMEQYGDEKNPLYKYYEETGNYLTKYSKKDNGPVIKKIKYYGNKLNAHLDITDD YPNSRNKVVKLSLKPYRFDVYLDNGVYKFVTVKNLDVIKKENYYEVNSKCYEEAKKLKKISNQA EFIASFYNNDLIKINGELYRVIGVNNDLLNRIEVNMIDITYREYLENMNDKRPPRIIKTIASKT QSIKKYSTDILGNLYEVKSKKHPQIIKKG SEQ ID NO: 305 MDKKYSIGLDIGTNSVGWAVITDEYKVPSKKFKVLGNTDRHSIKKNLIGALLFDSGETAEATRL KRTARRRYTRRKNRICYLQEIFSNEMAKVDDSFFHRLEESFLVEEDKKHERHPIFGNIVDEVAY HEKYPTIYHLRKKLVDSTDKADLRLIYLALAHMIKFRGHFLIEGDLNPDNSDVDKLFIQLVQTY NQLFEENPINASGVDAKAILSARLSKSRRLENLIAQLPGEKKNGLFGNLIALSLGLTPNFKSNF DLAEDAKLQLSKDTYDDDLDNLLAQIGDQYADLFLAAKNLSDAILLSDILRVNTEITKAPLSAS MIKRYDEHHQDLTLLKALVRQQLPEKYKEIFFDQSKNGYAGYIDGGASQEEFYKFIKPILEKMD GTEELLVKLNREDLLRKQRTFDNGSIPHQIHLGELHAILRRQEDFYPFLKDNREKIEKILTFRI PYYVGPLARGNSRFAWMTRKSEETITPWNFEEVVDKGASAQSFIERMTNFDKNLPNEKVLPKHS LLYEYFTVYNELTKVKYVTEGMRKPAFLSGEQKKAIVDLLFKTNRKVTVKQLKEDYFKKIECFD SVEISGVEDRFNASLGTYHDLLKIIKDKDFLDNEENEDILEDIVLTLTLFEDREMIEERLKTYA HLFDDKVMKQLKRRRYTGWGRLSRKLINGIRDKQSGKTILDFLKSDGFANRNFMQLIHDDSLTF KEDIQKAQVSGQGDSLHEHIANLAGSPAIKKGILQTVKVVDELVKVMGRHKPENIVIEMARENQ TTQKGQKNSRERMKRIEEGIKELGSQILKEHPVENTQLQNEKLYLYYLQNGRDMYVDQELDINR LSDYDVDHIVPQSFLKDDSIDNKVLTRSDKNRGKSDNVPSEEVVKKMKNYWRQLLNAKLITQRK FDNLTKAERGGLSELDKAGFIKRQLVETRQITKHVAQILDSRMNTKYDENDKLIREVKVITLKS KLVSDFRKDFQFYKVREINNYHHAHDAYLNAVVGTALIKKYPKLESEFVYGDYKVYDVRKMIAK SEQEIGKATAKYFEYSNIMNEFKTEITLANGEIRKRPLIETNGETGEIVWDKGRDFATVRKVLS MPQVNIVKKTEVQTGGFSKESILPKRNSDKLIARKKDWDPKKYGGFDSPTVAYSVLVVAKVEKG KSKKLKSVKELLGITIMERSSFEKNPIDFLEAKGYKEVKKDLIIKLPKYSLFELENGRKRMLAS AGELQKGNELALPSKYVNFLYLASHYEKLKGSPEDNEQKQLFVEQHKHYLDEIIEQISEFSKRV ILADANLDKVLSAYNKHRDKPIREQAENIIHLFTLTNLGAPAAFKYFDTTIDRKRYTSTKEVLD ATLIHQSITGLYETRIDLSQLGGD SEQ ID NO: 306 MARILAFDIGISSIGWAFSENDELKDCGVRIFTKVENPKTGESLALPRRLARSARKRLARRKAR LNHLKHLIANEFKLNYEDYQSFDESLAKAYKGSLISPYELRFRALNELLSKQDFARVILHIAKR RGYDDIKNSDDKEKGAILKAIKQNEEKLANYQSVGEYLYKEYFQKFKENSKEFTNVRNKKESYE RCIAQSFLKDELKLIFKKQREFGFSFSKKFEEEVLSVAFYKRALKDFSHLVGNCSFFTDEKRAP KNSPLAFMEVALTRIINLLNNLKNTEGILYTKDDLNALLNEVLKNGTLTYKQTKKLLGLSDDYE FKGEKGTYFIEFKKYKEFIKALGEHNLSQDDLNEIAKDITLIKDEIKLKKALAKYDLNQNQIDS LSKLEFKDHLNISFKALKLVTPLMLEGKKYDEACNELNLKVAINEDKKDFLPAFNETYYKDEVT NPVVLRAIKEYRKVLNALLKKYGKVHKINIELAREVGKNHSQRAKIEKEQNENYKAKKDAELEC EKLGLKINSKNILKLRLFKEQKEFCAYSGEKIKISDLQDEKMLEIDHIYPYSRSFDDSYMNKVL VFTKQNQEKLNQTPFEAFGNDSAKWQKIEVLAKNLPTKKQKRILDKNYKDKEQKNFKDRNLNDT RYIARLVLNYTKDYLDFLPLSDDENTKLNDTQKGSKVHVEAKSGMLTSALRHTWGFSAKDRNNH LHHAIDAVIIAYANNSIVKAFSDFKKEQESNSAELYAKKISELDYKNKRKFFEPFSGFRQKVLD KIDEIFVSKPERKKPSGALHEETFRKEEEFYQSYGGKEGVLKALELGKIRKVNGKIVKNGDMFR VDIFKHKKTNKFYAVPIYTMDFALKVLPNKAVARSKKGEIKDWILMDENYEFCESLYKDSLILI QTKDMQEPEFVYYNAFTSSTVSLIVSKHDNKFETLSKNQKILFKNANEKEVIAKSIGIQNLKVF EKYIVSALGEVTKAEFRQREDFKK SEQ ID NO: 307 MKRILGLDLGTNSIGWALVNEAENKDERSSIVKLGVRVNPLTVDELTNFEKGKSITTNADRTLK RGMRRNLQRYKLRRETLTEVLKEHKLITEDTILSENGNRTTFETYRLRAKAVTEEISLEEFARV LLMINKKRGYKSSRKAKGVEEGTLIDGMDIARELYNNNLTPGELCLQLLDAGKKFLPDFYRSDL QNELDRIWEKQKEYYPEILTDVLKEELRGKKRDAVWAICAKYFVWKENYTEWNKEKGKTEQQER EHKLEGIYSKRKRDEAKRENLQWRVNGLKEKLSLEQLVIVFQEMNTQINNSSGYLGAISDRSKE LYFNKQTVGQYQMEMLDKNPNASLRNMVFYRQDYLDEFNMLWEKQAVYHKELTEELKKEIRDII IFYQRRLKSQKGLIGFCEFESRQIEVDIDGKKKIKTVGNRVISRSSPLFQEFKIWQILNNIEVT VVGKKRKRRKLKENYSALFEELNDAEQLELNGSRRLCQEEKELLAQELFIRDKMTKSEVLKLLF DNPQELDLNFKTIDGNKTGYALFQAYSKMIEMSGHEPVDFKKPVEKVVEYIKAVFDLLNWNTDI LGFNSNEELDNQPYYKLWHLLYSFEGDNTPTGNGRLIQKMTELYGFEKEYATILANVSFQDDYG SLSAKAIHKILPHLKEGNRYDVACVYAGYRHSESSLTREEIANKVLKDRLMLLPKNSLHNPVVE KILNQMVNVINVIIDIYGKPDEIRVELARELKKNAKEREELTKSIAQTTKAHEEYKTLLQTEFG LTNVSRTDILRYKLYKELESCGYKTLYSNTYISREKLFSKEFDIEHIIPQARLFDDSFSNKTLE ARSVNIEKGNKTAYDFVKEKFGESGADNSLEHYLNNIEDLFKSGKISKTKYNKLKMAEQDIPDG FIERDLRNTQYIAKKALSMLNEISHRVVATSGSVTDKLREDWQLIDVMKELNWEKYKALGLVEY FEDRDGRQIGRIKDWTKRNDHRHHAMDALTVAFTKDVFIQYFNNKNASLDPNANEHAIKNKYFQ NGRAIAPMPLREFRAEAKKHLENTLISIKAKNKVITGNINKTRKKGGVNKNMQQTPRGQLHLET IYGSGKQYLTKEEKVNASFDMRKIGTVSKSAYRDALLKRLYENDNDPKKAFAGKNSLDKQPIWL DKEQMRKVPEKVKIVTLEAIYTIRKEISPDLKVDKVIDVGVRKILIDRLNEYGNDAKKAFSNLD KNPIWLNKEKGISIKRVTISGISNAQSLHVKKDKDGKPILDENGRNIPVDFVNTGNNHHVAVYY RPVIDKRGQLVVDEAGNPKYELEEVVVSFFEAVTRANLGLPIIDKDYKTTEGWQFLFSMKQNEY FVFPNEKTGFNPKEIDLLDVENYGLISPNLFRVQKFSLKNYVFRHHLETTIKDTSSILRGITWI DFRSSKGLDTIVKVRVNHIGQIVSVGEY SEQ ID NO: 308 MSRKNYVDDYAISLDIGNASVGWSAFTPNYRLVRAKGHELIGVRLFDPADTAESRRMARTTRRR YSRRRWRLRLLDALFDQALSEIDPSFLARRKYSWVHPDDENNADCWYGSVLFDSNEQDKRFYEK YPTIYHLRKALMEDDSQHDIREIYLAIHHMVKYRGNFLVEGTLESSNAFKEDELLKLLGRITRY EMSEGEQNSDIEQDDENKLVAPANGQLADALCATRGSRSMRVDNALEALSAVNDLSREQRAIVK AIFAGLEGNKLDLAKIFVSKEFSSENKKILGIYFNKSDYEEKCVQIVDSGLLDDEEREFLDRMQ GQYNAIALKQLLGRSTSVSDSKCASYDAHRANWNLIKLQLRTKENEKDINENYGILVGWKIDSG QRKSVRGESAYENMRKKANVFFKKMIETSDLSETDKNRLIHDIEEDKLFPIQRDSDNGVIPHQL HQNELKQIIKKQGKYYPFLLDAFEKDGKQINKIEGLLTFRVPYFVGPLVVPEDLQKSDNSENHW MVRKKKGEITPWNFDEMVDKDASGRKFIERLVGTDSYLLGEPTLPKNSLLYQEYEVLNELNNVR LSVRTGNHWNDKRRMRLGREEKTLLCQRLFMKGQTVTKRTAENLLRKEYGRTYELSGLSDESKF TSSLSTYGKMCRIFGEKYVNEHRDLMEKIVELQTVFEDKETLLHQLRQLEGISEADCALLVNTH YTGWGRLSRKLLTTKAGECKISDDFAPRKHSIIEIMRAEDRNLMEIITDKQLGFSDWIEQENLG AENGSSLMEVVDDLRVSPKVKRGIIQSIRLIDDISKAVGKRPSRIFLELADDIQPSGRTISRKS RLQDLYRNANLGKEFKGIADELNACSDKDLQDDRLFLYYTQLGKDMYTGEELDLDRLSSAYDID HIIPQAVTQNDSIDNRVLVARAENARKTDSFTYMPQIADRMRNFWQILLDNGLISRVKFERLTR QNEFSEREKERFVQRSLVETRQIMKNVATLMRQRYGNSAAVIGLNAELTKEMHRYLGFSHKNRD INDYHHAQDALCVGIAGQFAANRGFFADGEVSDGAQNSYNQYLRDYLRGYREKLSAEDRKQGRA FGFIVGSMRSQDEQKRVNPRTGEVVWSEEDKDYLRKVMNYRKMLVTQKVGDDFGALYDETRYAA TDPKGIKGIPFDGAKQDTSLYGGFSSAKPAYAVLIESKGKTRLVNVTMQEYSLLGDRPSDDELR KVLAKKKSEYAKANILLRHVPKMQLIRYGGGLMVIKSAGELNNAQQLWLPYEEYCYFDDLSQGK GSLEKDDLKKLLDSILGSVQCLYPWHRFTEEELADLHVAFDKLPEDEKKNVITGIVSALHADAK TANLSIVGMTGSWRRMNNKSGYTFSDEDEFIFQSPSGLFEKRVTVGELKRKAKKEVNSKYRTNE KRLPTLSGASQP SEQ ID NO: 309 METQTSNQLITSHLKDYPKQDYFVGLDIGTNSVGWAVTNTSYELLKFHSHKMWGSRLFEEGESA VTRRGFRSMRRRLERRKLRLKLLEELFADAMAQVDSTFFIRLHESKYHYEDKTTGHSSKHILFI DEDYTDQDYFTEYPTIYHLRKDLMENGTDDIRKLFLAVHHILKYRGNFLYEGATFNSNAFTFED VLKQALVNITFNCFDTNSAISSISNILMESGKTKSDKAKAIERLVDTYTVFDEVNTPDKPQKEQ VKEDKKTLKAFANLVLGLSANLIDLFGSVEDIDDDLKKLQIVGDTYDEKRDELAKVWGDEIHII DDCKSVYDAIILMSIKEPGLTISQSKVKAFDKHKEDLVILKSLLKLDRNVYNEMFKSDKKGLHN YVHYIKQGRTEETSCSREDFYKYTKKIVEGLADSKDKEYILNEIELQTLLPLQRIKDNGVIPYQ LHLEELKVILDKCGPKFPFLHTVSDGFSVTEKLIKMLEFRIPYYVGPLNTHHNIDNGGFSWAVR KQAGRVTPWNFEEKIDREKSAAAFIKNLTNKCTYLFGEDVLPKSSLLYSEFMLLNELNNVRIDG KALAQGVKQHLIDSIFKQDHKKMTKNRIELFLKDNNYITKKHKPEITGLDGEIKNDLTSYRDMV RILGNNFDVSMAEDIITDITIFGESKKMLRQTLRNKFGSQLNDETIKKLSKLRYRDWGRLSKKL LKGIDGCDKAGNGAPKTIIELMRNDSYNLMEILGDKFSFMECIEEENAKLAQGQVVNPHDIIDE LALSPAVKRAVWQALRIVDEVAHIKKALPSRIFVEVARTNKSEKKKKDSRQKRLSDLYSAIKKD DVLQSGLQDKEFGALKSGLANYDDAALRSKKLYLYYTQMGRCAYTGNIIDLNQLNTDNYDIDHI YPRSLTKDDSFDNLVLCERTANAKKSDIYPIDNRIQTKQKPFWAFLKHQGLISERKYERLTRIA PLTADDLSGFIARQLVETNQSVKATTTLLRRLYPDIDVVFVKAENVSDFRHNNNFIKVRSLNHH HHAKDAYLNIVVGNVYHEKFTRNFRLFFKKNGANRTYNLAKMFNYDVICTNAQDGKAWDVKTSM NTVKKMMASNDVRVTRRLLEQSGALADATIYKASVAAKAKDGAYIGMKTKYSVFADVTKYGGMT KIKNAYSIIVQYTGKKGEEIKEIVPLPIYLINRNATDIELIDYVKSVIPKAKDISIKYRKLCIN QLVKVNGFYYYLGGKTNDKIYIDNAIELVVPHDIATYIKLLDKYDLLRKENKTLKASSITTSIY NINTSTVVSLNKVGIDVFDYFMSKLRTPLYMKMKGNKVDELSSTGRSKFIKMTLEEQSIYLLEV LNLLTNSKTTFDVKPLGITGSRSTIGVKIHNLDEFKIINESITGLYSNEVTIV SEQ ID NO: 310 MTKLNQPYGIGLDIGSNSIGFAVVDANSHLLRLKGETAIGARLFREGQSAADRRGSRTTRRRLS RTRWRLSFLRDFFAPHITKIDPDFFLRQKYSEISPKDKDRFKYEKRLFNDRTDAEFYEDYPSMY HLRLHLMTHTHKADPREIFLAIHHILKSRGHFLTPGAAKDFNTDKVDLEDIFPALTEAYAQVYP DLELTFDLAKADDFKAKLLDEQATPSDTQKALVNLLLSSDGEKEIVKKRKQVLTEFAKAITGLK TKFNLALGTEVDEADASNWQFSMGQLDDKWSNIETSMTDQGTEIFEQIQELYRARLLNGIVPAG MSLSQAKVADYGQHKEDLELFKTYLKKLNDHELAKTIRGLYDRYINGDDAKPFLREDFVKALTK EVTAHPNEVSEQLLNRMGQANFMLKQRTKANGAIPIQLQQRELDQIIANQSKYYDWLAAPNPVE AHRWKMPYQLDELLNFHIPYYVGPLITPKQQAESGENVFAWMVRKDPSGNITPYNFDEKVDREA SANTFIQRMKTTDTYLIGEDVLPKQSLLYQKYEVLNELNNVRINNECLGTDQKQRLIREVFERH SSVTIKQVADNLVAHGDFARRPEIRGLADEKRFLSSLSTYHQLKEILHEAIDDPTKLLDIENII TWSTVFEDHTIFETKLAEIEWLDPKKINELSGIRYRGWGQFSRKLLDGLKLGNGHTVIQELMLS NHNLMQILADETLKETMTELNQDKLKTDDIEDVINDAYTSPSNKKALRQVLRVVEDIKHAANGQ DPSWLFIETADGTGTAGKRTQSRQKQIQTVYANAAQELIDSAVRGELEDKIADKASFTDRLVLY FMQGGRDIYTGAPLNIDQLSHYDIDHILPQSLIKDDSLDNRVLVNATINREKNNVFASTLFAGK MKATWRKWHEAGLISGRKLRNLMLRPDEIDKFAKGFVARQLVETRQIIKLTEQIAAAQYPNTKI IAVKAGLSHQLREELDFPKNRDVNHYHHAFDAFLAARIGTYLLKRYPKLAPFFTYGEFAKVDVK KEREFNFIGALTHAKKNIIAKDTGEIVWDKERDIRELDRIYNFKRMLITHEVYFETADLFKQTI YAAKDSKERGGSKQLIPKKQGYPTQVYGGYTQESGSYNALVRVAEADTTAYQVIKISAQNASKI ASANLKSREKGKQLLNEIVVKQLAKRRKNWKPSANSFKIVIPRFGMGTLFQNAKYGLFMVNSDT YYRNYQELWLSRENQKLLKKLFSIKYEKTQMNHDALQVYKAIIDQVEKFFKLYDINQFRAKLSD AIERFEKLPINTDGNKIGKTETLRQILIGLQANGTRSNVKNLGIKTDLGLLQVGSGIKLDKDTQ IVYQSPSGLFKRRIPLADL SEQ ID NO: 311 MTKEYYLGLDVGTNSVGWAVTDSQYNLCKFKKKDMWGIRLFESANTAKDRRLQRGNRRRLERKK QRIDLLQEIFSPEICKIDPTFFIRLNESRLHLEDKSNDFKYPLFIEKDYSDIEYYKEFPTIFHL RKHLIESEEKQDIRLIYLALHNIIKTRGHFLIDGDLQSAKQLRPILDTFLLSLQEEQNLSVSLS ENQKDEYEEILKNRSIAKSEKVKKLKNLFEISDELEKEEKKAQSAVIENFCKFIVGNKGDVCKF LRVSKEELEIDSFSFSEGKYEDDIVKNLEEKVPEKVYLFEQMKAMYDWNILVDILETEEYISFA KVKQYEKHKTNLRLLRDIILKYCTKDEYNRMFNDEKEAGSYTAYVGKLKKNNKKYWIEKKRNPE EFYKSLGKLLDKIEPLKEDLEVLTMMIEECKNHTLLPIQKNKDNGVIPHQVHEVELKKILENAK KYYSFLTETDKDGYSVVQKIESIFRFRIPYYVGPLSTRHQEKGSNVWMVRKPGREDRIYPWNME EIIDFEKSNENFITRMTNKCTYLIGEDVLPKHSLLYSKYMVLNELNNVKVRGKKLPTSLKQKVF EDLFENKSKVTGKNLLEYLQIQDKDIQIDDLSGFDKDFKTSLKSYLDFKKQIFGEEIEKESIQN MIEDIIKWITIYGNDKEMLKRVIRANYSNQLTEEQMKKITGFQYSGWGNFSKMFLKGISGSDVS TGETEDIITAMWETDNNLMQILSKKETFMDNVEDENSGKVGKIDKITYDSTVKEMELSPENKRA VWQTIQVAEEIKKVMGCEPKKIFIEMARGGEKVKKRTKSRKAQLLELYAACEEDCRELIKEIED RDERDFNSMKLFLYYTQFGKCMYSGDDIDINELIRGNSKWDRDHIYPQSKIKDDSIDNLVLVNK TYNAKKSNELLSEDIQKKMHSFWLSLLNKKLITKSKYDRLTRKGDFTDEELSGFIARQLVETRQ STKAIADIFKQIYSSEVVYVKSSLVSDFRKKPLNYLKSRRVNDYHHAKDAYLNIVVGNVYNKKF TSNPIQWMKKNRDTNYSLNKVFEHDVVINGEVIWEKCTYHEDTNTYDGGTLDRIRKIVERDNIL YTEYAYCEKGELENATIQNKNGNSTVSLKKGLDVKKYGGYFSANTSYFSLIEFEDKKGDRARHI IGVPIYIANMLEHSPSAFLEYCEQKGYQNVRILVEKIKKNSLLIINGYPLRIRGENEVDTSFKR AIQLKLDQKNYELVRNIEKFLEKYVEKKGNYPIDENRDHITHEKMNQLYEVLLSKMKKFNKKGM ADPSDRIEKSKPKFIKLEDLIDKINVINKMLNLLRCDNDTKADLSLIELPKNAGSFVVKKNTIG KSKIILVNQSVTGLYENRREL SEQ ID NO: 312 MARDYSVGLDIGTSSVGWAAIDNKYHLIRAKSKNLIGVRLFDSAVTAEKRRGYRTTRRRLSRRH WRLRLLNDIFAGPLTDFGDENFLARLKYSWVHPQDQSNQAHFAAGLLFDSKEQDKDFYRKYPTI YHLRLALMNDDQKHDLREVYLAIHHLVKYRGHFLIEGDVKADSAFDVHTFADAIQRYAESNNSD ENLLGKIDEKKLSAALTDKHGSKSQRAETAETAFDILDLQSKKQIQAILKSVVGNQANLMAIFG LDSSAISKDEQKNYKFSFDDADIDEKIADSEALLSDTEFEFLCDLKAAFDGLTLKMLLGDDKTV SAAMVRRFNEHQKDWEYIKSHIRNAKNAGNGLYEKSKKFDGINAAYLALQSDNEDDRKKAKKIF QDEISSADIPDDVKADFLKKIDDDQFLPIQRTKNNGTIPHQLHRNELEQIIEKQGIYYPFLKDT YQENSHELNKITALINFRVPYYVGPLVEEEQKIADDGKNIPDPTNHWMVRKSNDTITPWNLSQV VDLDKSGRRFIERLTGTDTYLIGEPTLPKNSLLYQKFDVLQELNNIRVSGRRLDIRAKQDAFEH LFKVQKTVSATNLKDFLVQAGYISEDTQIEGLADVNGKNFNNALTTYNYLVSVLGREFVENPSN EELLEEITELQTVFEDKKVLRRQLDQLDGLSDHNREKLSRKHYTGWGRISKKLLTTKIVQNADK IDNQTFDVPRMNQSIIDTLYNTKMNLMEIINNAEDDFGVRAWIDKQNTTDGDEQDVYSLIDELA GPKEIKRGIVQSFRILDDITKAVGYAPKRVYLEFARKTQESHLTNSRKNQLSTLLKNAGLSELV TQVSQYDAAALQNDRLYLYFLQQGKDMYSGEKLNLDNLSNYDIDHIIPQAYTKDNSLDNRVLVS NITNRRKSDSSNYLPALIDKMRPFWSVLSKQGLLSKHKFANLTRTRDFDDMEKERFIARSLVET RQIIKNVASLIDSHFGGETKAVAIRSSLTADMRRYVDIPKNRDINDYHHAFDALLESTVGQYTE NSGLMKKGQLSDSAGNQYNRYIKEWIHAARLNAQSQRVNPFGFVVGSMRNAAPGKLNPETGEIT PEENADWSIADLDYLHKVMNFRKITVTRRLKDQKGQLYDESRYPSVLHDAKSKASINFDKHKPV DLYGGFSSAKPAYAALIKFKNKFRLVNVLRQWTYSDKNSEDYILEQIRGKYPKAEMVLSHIPYG QLVKKDGALVTISSATELHNFEQLWLPLADYKLINTLLKTKEDNLVDILHNRLDLPEMTIESAF YKAFDSILSFAFNRYALHQNALVKLQAHRDDFNALNYEDKQQTLERILDALHASPASSDLKKIN LSSGFGRLFSPSHFTLADTDEFIFQSVTGLFSTQKTVAQLYQETK SEQ ID NO: 313 MVYDVGLDIGTGSVGWVALDENGKLARAKGKNLVGVRLFDTAQTAADRRGFRTTRRRLSRRKWR LRLLDELFSAEINEIDSSFFQRLKYSYVHPKDEENKAHYYGGYLFPTEEETKKFHRSYPTIYHL RQELMAQPNKRFDIREIYLAIHHLVKYRGHFLSSQEKITIGSTYNPEDLANAIEVYADEKGLSW ELNNPEQLTEIISGEAGYGLNKSMKADEALKLFEFDNNQDKVAIKTLLAGLTGNQIDFAKLFGK DISDKDEAKLWKLKLDDEALEEKSQTILSQLTDEEIELFHAVVQAYDGFVLIGLLNGADSVSAA MVQLYDQHREDRKLLKSLAQKAGLKHKRFSEIYEQLALATDEATIKNGISTARELVEESNLSKE VKEDTLRRLDENEFLPKQRTKANSVIPHQLHLAELQKILQNQGQYYPFLLDTFEKEDGQDNKIE ELLRFRIPYYVGPLVTKKDVEHAGGDADNHWVERNEGFEKSRVTPWNFDKVFNRDKAARDFIER LTGNDTYLIGEKTLPQNSLRYQLFTVLNELNNVRVNGKKFDSKTKADLINDLFKARKTVSLSAL KDYLKAQGKGDVTITGLADESKFNSSLSSYNDLKKTFDAEYLENEDNQETLEKIIEIQTVFEDS KIASRELSKLPLDDDQVKKLSQTHYTGWGRLSEKLLDSKIIDERGQKVSILDKLKSTSQNFMSI INNDKYGVQAWITEQNTGSSKLTFDEKVNELTTSPANKRGIKQSFAVLNDIKKAMKEEPRRVYL EFAREDQTSVRSVPRYNQLKEKYQSKSLSEEAKVLKKTLDGNKNKMSDDRYFLYFQQQGKDMYT GRPINFERLSQDYDIDHIIPQAFTKDDSLDNRVLVSRPENARKSDSFAYTDEVQKQDGSLWTSL LKSGFINRKKYERLTKAGKYLDGQKTGFIARQLVETRQIIKNVASLIEGEYENSKAVAIRSEIT ADMRLLVGIKKHREINSFHHAFDALLITAAGQYMQNRYPDRDSTNVYNEFDRYTNDYLKNLRQL SSRDEVRRLKSFGEVVGTMRKGNEDWSEENTSYLRKVMMFKNILTTKKTEKDRGPLNKETIFSP KSGKKLIPLNSKRSDTALYGGYSNVYSAYMTLVRANGKNLLIKIPISIANQIEVGNLKINDYIV NNPAIKKFEKILISKLPLGQLVNEDGNLIYLASNEYRHNAKQLWLSTTDADKIASISENSSDEE LLEAYDILTSENVKNRFPFFKKDIDKLSQVRDEFLDSDKRIAVIQTILRGLQIDAAYQAPVKII SKKVSDWHKLQQSGGIKLSDNSEMIYQSATGIFETRVKISDLL SEQ ID NO: 314 IVDYCIGLDLGTGSVGWAVVDMNHRLMKRNGKHLWGSRLFSNAETAANRRASRSIRRRYNKRRE RIRLLRAILQDMVLEKDPTFFIRLEHTSFLDEEDKAKYLGTDYKDNYNLFIDEDFNDYTYYHKY PTIYHLRKALCESTEKADPRLIYLALHHIVKYRGNFLYEGQKFNMDASNIEDKLSDIFTQFTSF NNIPYEDDEKKNLEILEILKKPLSKKAKVDEVMTLIAPEKDYKSAFKELVTGIAGNKMNVTKMI LCEPIKQGDSEIKLKFSDSNYDDQFSEVEKDLGEYVEFVDALHNVYSWVELQTIMGATHTDNAS ISEAMVSRYNKHHDDLKLLKDCIKNNVPNKYFDMFRNDSEKSKGYYNYINRPSKAPVDEFYKYV KKCIEKVDTPEAKQILNDIELENFLLKQNSRTNGSVPYQMQLDEMIKIIDNQAEYYPILKEKRE QLLSILTFRIPYYFGPLNETSEHAWIKRLEGKENQRILPWNYQDIVDVDATAEGFIKRMRSYCT YFPDEEVLPKNSLIVSKYEVYNELNKIRVDDKLLEVDVKNDIYNELFMKNKTVTEKKLKNWLVN NQCCSKDAEIKGFQKENQFSTSLTPWIDFTNIFGKIDQSNFDLIENIIYDLTVFEDKKIMKRRL KKKYALPDDKVKQILKLKYKDWSRLSKKLLDGIVADNRFGSSVTVLDVLEMSRLNLMEIINDKD LGYAQMIEEATSCPEDGKFTYEEVERLAGSPALKRGIWQSLQIVEEITKVMKCRPKYIYIEFER SEEAKERTESKIKKLENVYKDLDEQTKKEYKSVLEELKGFDNTKKISSDSLFLYFTQLGKCMYS GKKLDIDSLDKYQIDHIVPQSLVKDDSFDNRVLVVPSENQRKLDDLVVPFDIRDKMYRFWKLLF DHELISPKKFYSLIKTEYTERDEERFINRQLVETRQITKNVTQIIEDHYSTTKVAAIRANLSHE FRVKNHIYKNRDINDYHHAHDAYIVALIGGFMRDRYPNMHDSKAVYSEYMKMFRKNKNDQKRWK DGFVINSMNYPYEVDGKLIWNPDLINEIKKCFYYKDCYCTTKLDQKSGQLFNLTVLSNDAHADK GVTKAVVPVNKNRSDVHKYGGFSGLQYTIVAIEGQKKKGKKTELVKKISGVPLHLKAASINEKI NYIEEKEGLSDVRIIKDNIPVNQMIEMDGGEYLLTSPTEYVNARQLVLNEKQCALIADIYNAIY KQDYDNLDDILMIQLYIELTNKMKVLYPAYRGIAEKFESMNENYVVISKEEKANIIKQMLIVMH RGPQNGNIVYDDFKISDRIGRLKTKNHNLNNIVFISQSPTGIYTKKYKL SEQ ID NO: 315 MKSEKKYYIGLDVGTNSVGWAVTDEFYNILRAKGKDLWGVRLFEKADTAANTRIFRSGRRRNDR KGMRLQILREIFEDEIKKVDKDFYDRLDESKFWAEDKKVSGKYSLFNDKNFSDKQYFEKFPTIF HLRKYLMEEHGKVDIRYYFLAINQMMKRRGHFLIDGQISHVTDDKPLKEQLILLINDLLKIELE EELMDSIEEILADVNEKRTDKKNNLKELIKGQDFNKQEGNILNSIEESIVTGKAKIKNIISDED ILEKIKEDNKEDFVLTGDSYEENLQYFEEVLQENITLFNTLKSTYDFLILQSILKGKSTLSDAQ VERYDEHKKDLEILKKVIKKYDEDGKLFKQVFKEDNGNGYVSYIGYYLNKNKKITAKKKISNIE FTKYVKGILEKQCDCEDEDVKYLLGKIEQENFLLKQISSINSVIPHQIHLFELDKILENLAKNY PSFNNKKEEFTKIEKIRKTFTFRIPYYVGPLNDYHKNNGGNAWIFRNKGEKIRPWNFEKIVDLH KSEEEFIKRMLNQCTYLPEETVLPKSSILYSEYMVLNELNNLRINGKPLDTDVKLKLIEELFKK KTKVTLKSIRDYMVRNNFADKEDFDNSEKNLEIASNMKSYIDFNNILEDKFDVEMVEDLIEKIT IHTGNKKLLKKYIEETYPDLSSSQIQKIINLKYKDWGRLSRKLLDGIKGTKKETEKTDTVINFL RNSSDNLMQIIGSQNYSFNEYIDKLRKKYIPQEISYEVVENLYVSPSVKKMIWQVIRVTEEITK VMGYDPDKIFIEMAKSEEEKKTTISRKNKLLDLYKAIKKDERDSQYEKLLTGLNKLDDSDLRSR KLYLYYTQMGRDMYTGEKIDLDKLFDSTHYDKDHIIPQSMKKDDSIINNLVLVNKNANQTTKGN IYPVPSSIRNNPKIYNYWKYLMEKEFISKEKYNRLIRNTPLTNEELGGFINRQLVETRQSTKAI KELFEKFYQKSKIIPVKASLASDLRKDMNTLKSREVNDLHHAHDAFLNIVAGDVWNREFTSNPI NYVKENREGDKVKYSLSKDFTRPRKSKGKVIWTPEKGRKLIVDTLNKPSVLISNESHVKKGELF NATIAGKKDYKKGKIYLPLKKDDRLQDVSKYGGYKAINGAFFFLVEHTKSKKRIRSIELEPLHL LSKFYEDKNTVLDYAINVLQLQDPKIIIDKINYRTEIIIDNFSYLISTKSNDGSITVKPNEQMY WRVDEISNLKKIENKYKKDAILTEEDRKIMESYIDKIYQQFKAGKYKNRRTTDTIIEKYEIIDL DTLDNKQLYQLLVAFISLSYKTSNNAVDFTVIGLGTECGKPRITNLPDNTYLVYKSITGIYEKR IRIK SEQ ID NO: 316 MKLRGIEDDYSIGLDMGTSSVGWAVTDERGTLAHFKRKPTWGSRLFREAQTAAVARMPRGQRRR YVRRRWRLDLLQKLFEQQMEQADPDFFIRLRQSRLLRDDRAEEHADYRWPLFNDCKFTERDYYQ RFPTIYHVRSWLMETDEQADIRLIYLALHNIVKHRGNFLREGQSLSAKSARPDEALNHLRETLR VWSSERGFECSIADNGSILAMLTHPDLSPSDRRKKIAPLFDVKSDDAAADKKLGIALAGAVIGL KTEFKNIFGDFPCEDSSIYLSNDEAVDAVRSACPDDCAELFDRLCEVYSAYVLQGLLSYAPGQT ISANMVEKYRRYGEDLALLKKLVKIYAPDQYRMFFSGATYPGTGIYDAAQARGYTKYNLGPKKS EYKPSESMQYDDFRKAVEKLFAKTDARADERYRMMMDRFDKQQFLRRLKTSDNGSIYHQLHLEE LKAIVENQGRFYPFLKRDADKLVSLVSFRIPYYVGPLSTRNARTDQHGENRFAWSERKPGMQDE PIFPWNWESIIDRSKSAEKFILRMTGMCTYLQQEPVLPKSSLLYEEFCVLNELNGAHWSIDGDD EHRFDAADREGIIEELFRRKRTVSYGDVAGWMERERNQIGAHVCGGQGEKGFESKLGSYIFECK DVFKVERLEQSDYPMIERIILWNTLFEDRKILSQRLKEEYGSRLSAEQIKTICKKRFTGWGRLS EKFLTGITVQVDEDSVSIMDVLREGCPVSGKRGRAMVMMEILRDEELGFQKKVDDFNRAFFAEN AQALGVNELPGSPAVRRSLNQSIRIVDEIASIAGKAPANIFIEVTRDEDPKKKGRRTKRRYNDL KDALEAFKKEDPELWRELCETAPNDMDERLSLYFMQRGKCLYSGRAIDIHQLSNAGIYEVDHII PRTYVKDDSLENKALVYREENQRKTDMLLIDPEIRRRMSGYWRMLHEAKLIGDKKFRNLLRSRI DDKALKGFIARQLVETGQMVKLVRSLLEARYPETNIISVKASISHDLRTAAELVKCREANDFHH AHDAFLACRVGLFIQKRHPCVYENPIGLSQVVRNYVRQQADIFKRCRTIPGSSGFIVNSFMTSG FDKETGEIFKDDWDAEAEVEGIRRSLNFRQCFISRMPFEDHGVFWDATIYSPRAKKTAALPLKQ GLNPSRYGSFSREQFAYFFIYKARNPRKEQTLFEFAQVPVRLSAQIRQDENALERYARELAKDQ GLEFIRIERSKILKNQLIEIDGDRLCITGKEEVRNACELAFAQDEMRVIRMLVSEKPVSRECVI SLFNRILLHGDQASRRLSKQLKLALLSEAFSEASDNVQRNVVLGLIAIFNGSTNMVNLSDIGGS KFAGNVRIKYKKELASPKVNVHLIDQSVTGMFERRTKIGL SEQ ID NO: 317 MENKQYYIGLDVGTNSVGWAVTDTSYNLLRAKGKDMWGARLFEKANTAAERRTKRTSRRRSERE KARKAMLKELFADEINRVDPSFFIRLEESKFFLDDRSENNRQRYTLFNDATFTDKDYYEKYKTI FHLRSALINSDEKFDVRLVFLAILNLFSHRGHFLNASLKGDGDIQGMDVFYNDLVESCEYFEIE LPRITNIDNFEKILSQKGKSRTKILEELSEELSISKKDKSKYNLIKLISGLEASVVELYNIEDI QDENKKIKIGFRESDYEESSLKVKEIIGDEYFDLVERAKSVHDMGLLSNIIGNSKYLCEARVEA YENHHKDLLKIKELLKKYDKKAYNDMFRKMTDKNYSAYVGSVNSNIAKERRSVDKRKIEDLYKY IEDTALKNIPDDNKDKIEILEKIKLGEFLKKQLTASNGVIPNQLQSRELRAILKKAENYLPFLK EKGEKNLTVSEMIIQLFEFQIPYYVGPLDKNPKKDNKANSWAKIKQGGRILPWNFEDKVDVKGS RKEFIEKMVRKCTYISDEHTLPKQSLLYEKFMVLNEINNIKIDGEKISVEAKQKIYNDLFVKGK KVSQKDIKKELISLNIMDKDSVLSGTDTVCNAYLSSIGKFTGVFKEEINKQSIVDMIEDIIFLK TVYGDEKRFVKEEIVEKYGDEIDKDKIKRILGFKFSNWGNLSKSFLELEGADVGTGEVRSIIQS LWETNFNLMELLSSRFTYMDELEKRVKKLEKPLSEWTIEDLDDMYLSSPVKRMIWQSMKIVDEI QTVIGYAPKRIFVEMTRSEGEKVRTKSRKDRLKELYNGIKEDSKQWVKELDSKDESYFRSKKMY LYYLQKGRCMYSGEVIELDKLMDDNLYDIDHIYPRSFVKDDSLDNLVLVKKEINNRKQNDPITP QIQASCQGFWKILHDQGFMSNEKYSRLTRKTQEFSDEEKLSFINRQIVETGQATKCMAQILQKS MGEDVDVVFSKARLVSEFRHKFELFKSRLINDFHHANDAYLNIVVGNSYFVKFTRNPANFIKDA RKNPDNPVYKYHMDRFFERDVKSKSEVAWIGQSEGNSGTIVIVKKTMAKNSPLITKKVEEGHGS ITKETIVGVKEIKFGRNKVEKADKTPKKPNLQAYRPIKTSDERLCNILRYGGRTSISISGYCLV EYVKKRKTIRSLEAIPVYLGRKDSLSEEKLLNYFRYNLNDGGKDSVSDIRLCLPFISTNSLVKI DGYLYYLGGKNDDRIQLYNAYQLKMKKEEVEYIRKIEKAVSMSKFDEIDREKNPVLTEEKNIEL YNKIQDKFENTVFSKRMSLVKYNKKDLSFGDFLKNKKSKFEEIDLEKQCKVLYNIIFNLSNLKE VDLSDIGGSKSTGKCRCKKNITNYKEFKLIQQSITGLYSCEKDLMTI SEQ ID NO: 318 MKNLKEYYIGLDIGTASVGWAVTDESYNIPKFNGKKMWGVRLFDDAKTAEERRTQRGSRRRLNR RKERINLLQDLFATEISKVDPNFFLRLDNSDLYREDKDEKLKSKYTLFNDKDFKDRDYHKKYPT IHHLIMDLIEDEGKKDIRLLYLACHYLLKNRGHFIFEGQKFDTKNSFDKSINDLKIHLRDEYNI DLEFNNEDLIEIITDTTLNKTNKKKELKNIVGDTKFLKAISAIMIGSSQKLVDLFEDGEFEETT VKSVDFSTTAFDDKYSEYEEALGDTISLLNILKSIYDSSILENLLKDADKSKDGNKYISKAFVK KFNKHGKDLKTLKRIIKKYLPSEYANIFRNKSINDNYVAYTKSNITSNKRTKASKFTKQEDFYK FIKKHLDTIKETKLNSSENEDLKLIDEMLTDIEFKTFIPKLKSSDNGVIPYQLKLMELKKILDN QSKYYDFLNESDEYGTVKDKVESIMEFRIPYYVGPLNPDSKYAWIKRENTKITPWNFKDIVDLD SSREEFIDRLIGRCTYLKEEKVLPKASLIYNEFMVLNELNNLKLNEFLITEEMKKAIFEELFKT KKKVTLKAVSNLLKKEFNLTGDILLSGTDGDFKQGLNSYIDFKNIIGDKVDRDDYRIKIEEIIK LIVLYEDDKTYLKKKIKSAYKNDFTDDEIKKIAALNYKDWGRLSKRFLTGIEGVDKTTGEKGSI IYFMREYNLNLMELMSGHYTFTEEVEKLNPVENRELCYEMVDELYLSPSVKRMLWQSLRVVDEI KRIIGKDPKKIFIEMARAKEAKNSRKESRKNKLLEFYKFGKKAFINEIGEERYNYLLNEINSEE ESKFRWDNLYLYYTQLGRCMYSLEPIDLADLKSNNIYDQDHIYPKSKIYDDSLENRVLVKKNLN HEKGNQYPIPEKVLNKNAYGFWKILFDKGLIGQKKYTRLTRRTPFEERELAEFIERQIVETRQA TKETANLLKNICQDSEIVYSKAENASRFRQEFDIIKCRTVNDLHHMHDAYLNIVVGNVYNTKFT KNPLNFIKDKDNVRSYNLENMFKYDVVRGSYTAWIADDSEGNVKAATIKKVKRELEGKNYRFTR MSYIGTGGLYDQNLMRKGKGQIPQKENTNKSNIEKYGGYNKASSAYFALIESDGKAGRERTLET IPIMVYNQEKYGNTEAVDKYLKDNLELQDPKILKDKIKINSLIKLDGFLYNIKGKTGDSLSIAG SVQLIVNKEEQKLIKKMDKFLVKKKDNKDIKVTSFDNIKEEELIKLYKTLSDKLNNGIYSNKRN NQAKNISEALDKFKEISIEEKIDVLNQIILLFQSYNNGCNLKSIGLSAKTGVVFIPKKLNYKEC KLINQSITGLFENEVDLLNL SEQ ID NO: 319 MGKMYYLGLDIGTNSVGYAVTDPSYHLLKFKGEPMWGAHVFAAGNQSAERRSFRTSRRRLDRRQ QRVKLVQEIFAPVISPIDPRFFIRLHESALWRDDVAETDKHIFFNDPTYTDKEYYSDYPTIHHL IVDLMESSEKHDPRLVYLAVAWLVAHRGHFLNEVDKDNIGDVLSFDAFYPEFLAFLSDNGVSPW VCESKALQATLLSRNSVNDKYKALKSLIFGSQKPEDNFDANISEDGLIQLLAGKKVKVNKLFPQ ESNDASFTLNDKEDAIEEILGTLTPDECEWIAHIRRLFDWAIMKHALKDGRTISESKVKLYEQH HHDLTQLKYFVKTYLAKEYDDIFRNVDSETTKNYVAYSYHVKEVKGTLPKNKATQEEFCKYVLG KVKNIECSEADKVDFDEMIQRLTDNSFMPKQVSGENRVIPYQLYYYELKTILNKAASYLPFLTQ CGKDAISNQDKLLSIMTFRIPYFVGPLRKDNSEHAWLERKAGKIYPWNFNDKVDLDKSEEAFIR RMTNTCTYYPGEDVLPLDSLIYEKFMILNEINNIRIDGYPISVDVKQQVFGLFEKKRRVTVKDI QNLLLSLGALDKHGKLTGIDTTIHSNYNTYHHFKSLMERGVLTRDDVERIVERMTYSDDTKRVR LWLNNNYGTLTADDVKHISRLRKHDFGRLSKMFLTGLKGVHKETGERASILDFMWNTNDNLMQL LSECYTFSDEITKLQEAYYAKAQLSLNDFLDSMYISNAVKRPIYRTLAVVNDIRKACGTAPKRI FIEMARDGESKKKRSVTRREQIKNLYRSIRKDFQQEVDFLEKILENKSDGQLQSDALYLYFAQL GRDMYTGDPIKLEHIKDQSFYNIDHIYPQSMVKDDSLDNKVLVQSEINGEKSSRYPLDAAIRNK MKPLWDAYYNHGLISLKKYQRLTRSTPFTDDEKWDFINRQLVETRQSTKALAILLKRKFPDTEI VYSKAGLSSDFRHEFGLVKSRNINDLHHAKDAFLAIVTGNVYHERFNRRWEMVNQPYSVKTKTL FTHSIKNGNFVAWNGEEDLGRIVKMLKQNKNTIHFTRFSFDRKEGLFDIQPLKASTGLVPRKAG LDVVKYGGYDKSTAAYYLLVRFTLEDKKTQHKLMMIPVEGLYKARIDHDKEFLTDYAQTTISEI LQKDKQKVINIMFPMGTRHIKLNSMISIDGFYLSIGGKSSKGKSVLCHAMVPLIVPHKIECYIK AMESFARKFKENNKLRIVEKFDKITVEDNLNLYELFLQKLQHNPYNKFFSTQFDVLTNGRSTFT KLSPEEQVQTLLNILSIFKTCRSSGCDLKSINGSAQAARIMISADLTGLSKKYSDIRLVEQSAS GLFVSKSQNLLEYL SEQ ID NO: 320 MTKKEQPYNIGLDIGTSSVGWAVTNDNYDLLNIKKKNLWGVRLFEEAQTAKETRLNRSTRRRYR RRKNRINWLNEIFSEELAKTDPSFLIRLQNSWVSKKDPDRKRDKYNLFIDGPYTDKEYYREFPT IFHLRKELILNKDKADIRLIYLALHNILKYRGNFTYEHQKFNISNLNNNLSKELIELNQQLIKY DISFPDDCDWNHISDILIGRGNATQKSSNILKDFTLDKETKKLLKEVINLILGNVAHLNTIFKT SLTKDEEKLNFSGKDIESKLDDLDSILDDDQFTVLDAANRIYSTITLNEILNGESYFSMAKVNQ YENHAIDLCKLRDMWHTTKNEEAVEQSRQAYDDYINKPKYGTKELYTSLKKFLKVALPTNLAKE AEEKISKGTYLVKPRNSENGVVPYQLNKIEMEKIIDNQSQYYPFLKENKEKLLSILSFRIPYYV GPLQSAEKNPFAWMERKSNGHARPWNFDEIVDREKSSNKFIRRMTVTDSYLVGEPVLPKNSLIY QRYEVLNELNNIRITENLKTNPIGSRLTVETKQRIYNELFKKYKKVTVKKLTKWLIAQGYYKNP ILIGLSQKDEFNSTLTTYLDMKKIFGSSFMEDNKNYDQIEELIEWLTIFEDKQILNEKLHSSKY SYTPDQIKKISNMRYKGWGRLSKKILMDITTETNTPQLLQLSNYSILDLMWATNNNFISIMSND KYDFKNYIENHNLNKNEDQNISDLVNDIHVSPALKRGITQSIKIVQEIVKFMGHAPKHIFIEVT RETKKSEITTSREKRIKRLQSKLLNKANDFKPQLREYLVPNKKIQEELKKHKNDLSSERIMLYF LQNGKSLYSEESLNINKLSDYQVDHILPRTYIPDDSLENKALVLAKENQRKADDLLLNSNVIDR NLERWTYMLNNNMIGLKKFKNLTRRVITDKDKLGFIHRQLVQTSQMVKGVANILDNMYKNQGTT CIQARANLSTAFRKALSGQDDTYHFKHPELVKNRNVNDFHHAQDAYLASFLGTYRLRRFPTNEM LLMNGEYNKFYGQVKELYSKKKKLPDSRKNGFIISPLVNGTTQYDRNTGEIIWNVGFRDKILKI FNYHQCNVTRKTEIKTGQFYDQTIYSPKNPKYKKLIAQKKDMDPNIYGGFSGDNKSSITIVKID NNKIKPVAIPIRLINDLKDKKTLQNWLEENVKHKKSIQIIKNNVPIGQIIYSKKVGLLSLNSDR EVANRQQLILPPEHSALLRLLQIPDEDLDQILAFYDKNILVEILQELITKMKKFYPFYKGEREF LIANIENFNQATTSEKVNSLEELITLLHANSTSAHLIFNNIEKKAFGRKTHGLTLNNTDFIYQS VTGLYETRIHIE SEQ ID NO: 321 MTKFNKNYSIGLDIGVSSVGYAVVTEDYRVPAFKFKVLGNTEKEKIKKNLIGSTTFVSAQPAKG TRVFRVNRRRIDRRNHRITYLRDIFQKEIEKVDKNFYRRLDESFRVLGDKSEDLQIKQPFFGDK ELETAYHKKYPTIYHLRKHLADADKNSPVADIREVYMAISHILKYRGHFLTLDKINPNNINMQN SWIDFIESCQEVFDLEISDESKNIADIFKSSENRQEKVKKILPYFQQELLKKDKSIFKQLLQLL FGLKTKFKDCFELEEEPDLNFSKENYDENLENFLGSLEEDFSDVFAKLKVLRDTILLSGMLTYT GATHARFSATMVERYEEHRKDLQRFKFFIKQNLSEQDYLDIFGRKTQNGFDVDKETKGYVGYIT NKMVLTNPQKQKTIQQNFYDYISGKITGIEGAEYFLNKISDGTFLRKLRTSDNGAIPNQIHAYE LEKIIERQGKDYPFLLENKDKLLSILTFKIPYYVGPLAKGSNSRFAWIKRATSSDILDDNDEDT RNGKIRPWNYQKLINMDETRDAFITNLIGNDIILLNEKVLPKRSLIYEEVMLQNELTRVKYKDK YGKAHEFDSELRQNIINGLFKNNSKRVNAKSLIKYLSDNHKDLNAIEIVSGVEKGKSFNSTLKT YNDLKTIFSEELLDSEIYQKELEEIIKVITVFDDKKSIKNYLTKFFGHLEILDEEKINQLSKLR YSGWGRYSAKLLLDIRDEDTGFNLLQFLRNDEENRNLTKLISDNTLSFEPKIKDIQSKSTIEDD IFDEIKKLAGSPAIKRGILNSIKIVDELVQIIGYPPHNIVIEMARENMTTEEGQKKAKTRKTKL ESALKNIENSLLENGKVPHSDEQLQSEKLYLYYLQNGKDMYTLDKTGSPAPLYLDQLDQYEVDH IIPYSFLPIDSIDNKVLTHRENNQQKLNNIPDKETVANMKPFWEKLYNAKLISQTKYQRLTTSE RTPDGVLTESMKAGFIERQLVETRQIIKHVARILDNRFSDTKIITLKSQLITNFRNTFHIAKIR ELNDYHHAHDAYLAVVVGQTLLKVYPKLAPELIYGHHAHFNRHEENKATLRKHLYSNIMRFFNN PDSKVSKDIWDCNRDLPIIKDVIYNSQINFVKRTMIKKGAFYNQNPVGKFNKQLAANNRYPLKT KALCLDTSIYGGYGPMNSALSIIIIAERFNEKKGKIETVKEFHDIFIIDYEKFNNNPFQFLNDT SENGFLKKNNINRVLGFYRIPKYSLMQKIDGTRMLFESKSNLHKATQFKLTKTQNELFFHMKRL LTKSNLMDLKSKSAIKESQNFILKHKEEFDNISNQLSAFSQKMLGNTTSLKNLIKGYNERKIKE IDIRDETIKYFYDNFIKMFSFVKSGAPKDINDFFDNKCTVARMRPKPDKKLLNATLIHQSITGL YETRIDLSKLGED SEQ ID NO: 322 MKQEYFLGLDMGTGSLGWAVTDSTYQVMRKHGKALWGTRLFESASTAEERRMFRTARRRLDRRN WRIQVLQEIFSEEISKVDPGFFLRMKESKYYPEDKRDAEGNCPELPYALFVDDNYTDKNYHKDY PTIYHLRKMLMETTEIPDIRLVYLVLHHMMKHRGHFLLSGDISQIKEFKSTFEQLIQNIQDEEL EWHISLDDAAIQFVEHVLKDRNLTRSTKKSRLIKQLNAKSACEKAILNLLSGGTVKLSDIFNNK ELDESERPKVSFADSGYDDYIGIVEAELAEQYYIIASAKAVYDWSVLVEILGNSVSISEAKIKV YQKHQADLKTLKKIVRQYMTKEDYKRVFVDTEEKLNNYSAYIGMTKKNGKKVDLKSKQCTQADF YDFLKKNVIKVIDHKEITQEIESEIEKENFLPKQVTKDNGVIPYQVHDYELKKILDNLGTRMPF IKENAEKIQQLFEFRIPYYVGPLNRVDDGKDGKFTWSVRKSDARIYPWNFTEVIDVEASAEKFI RRMTNKCTYLVGEDVLPKDSLVYSKFMVLNELNNLRLNGEKISVELKQRIYEELFCKYRKVTRK KLERYLVIEGIAKKGVEITGIDGDFKASLTAYHDFKERLTDVQLSQRAKEAIVLNVVLFGDDKK LLKQRLSKMYPNLTTGQLKGICSLSYQGWGRLSKTFLEEITVPAPGTGEVWNIMTALWQTNDNL MQLLSRNYGFTNEVEEFNTLKKETDLSYKTVDELYVSPAVKRQIWQTLKVVKEIQKVMGNAPKR VFVEMAREKQEGKRSDSRKKQLVELYRACKNEERDWITELNAQSDQQLRSDKLFLYYIQKGRCM YSGETIQLDELWDNTKYDIDHIYPQSKTMDDSLNNRVLVKKNYNAIKSDTYPLSLDIQKKMMSF WKMLQQQGFITKEKYVRLVRSDELSADELAGFIERQIVETRQSTKAVATILKEALPDTEIVYVK AGNVSNFRQTYELLKVREMNDLHHAKDAYLNIVVGNAYFVKFTKNAAWFIRNNPGRSYNLKRMF EEDIERSGEIAWKAGNKGSIVTVKKVMQKNNILVTRKAYEVKGGLFDQQIMKKGKGQVPIKGND ERLADIEKYGGYNKAAGTYFMLVKSLDKKGKEIRTIEFVPLYLKNQIEINHESAIQYLAQERGL NSPEILLSKIKIDTLFKVDGFKMWLSGRTGNQLIFKGANQLILSHQEAAILKGVVKYVNRKNEN KDAKLSERDGMTEEKLLQLYDTFLDKLSNTVYSIRLSAQIKTLTEKRAKFIGLSNEDQCIVLNE ILHMFQCQSGSANLKLIGGPGSAGILVMNNNITACKQISVINQSPTGIYEKEIDLIKL SEQ ID NO: 323 MKKPYSIGLDIGTNSVGWAVVTDDYKVPAKKMKVLGNTDKSHIEKNLLGALLFDSGNTAEDRRL KRTARRRYTRRRNRILYLQEIFSEEMGKVDDSFFHRLEDSFLVTEDKRGERHPIFGNLEEEVKY HENFPTIYHLRQYLADNPEKVDLRLVYLALAHIIKFRGHFLIEGKFDTRNNDVQRLFQEFLAVY DNTFENSSLQEQNVQVEEILTDKISKSAKKDRVLKLFPNEKSNGRFAEFLKLIVGNQADFKKHF ELEEKAPLQFSKDTYEEELEVLLAQIGDNYAELFLSAKKLYDSILLSGILTVTDVGTKAPLSAS MIQRYNEHQMDLAQLKQFIRQKLSDKYNEVFSDVSKDGYAGYIDGKTNQEAFYKYLKGLLNKIE GSGYFLDKIEREDFLRKQRTFDNGSIPHQIHLQEMRAIIRRQAEFYPFLADNQDRIEKLLTFRI PYYVGPLARGKSDFAWLSRKSADKITPWNFDEIVDKESSAEAFINRMTNYDLYLPNQKVLPKHS LLYEKFTVYNELTKVKYKTEQGKTAFFDANMKQEIFDGVFKVYRKVTKDKLMDFLEKEFDEFRI VDLTGLDKENKVFNASYGTYHDLCKILDKDFLDNSKNEKILEDIVLTLTLFEDREMIRKRLENY SDLLTKEQVKKLERRHYTGWGRLSAELIHGIRNKESRKTILDYLIDDGNSNRNFMQLINDDALS FKEEIAKAQVIGETDNLNQVVSDIAGSPAIKKGILQSLKIVDELVKIMGHQPENIVVEMARENQ FTNQGRRNSQQRLKGLTDSIKEFGSQILKEHPVENSQLQNDRLFLYYLQNGRDMYTGEELDIDY LSQYDIDHIIPQAFIKDNSIDNRVLTSSKENRGKSDDVPSKDVVRKMKSYWSKLLSAKLITQRK FDNLTKAERGGLTDDDKAGFIKRQLVETRQITKHVARILDERFNTETDENNKKIRQVKIVTLKS NLVSNFRKEFELYKVREINDYHHAHDAYLNAVIGKALLGVYPQLEPEFVYGDYPHFHGHKENKA TAKKFFYSNIMNFFKKDDVRTDKNGEIIWKKDEHISNIKKVLSYPQVNIVKKVEEQTGGFSKES ILPKGNSDKLIPRKTKKFYWDTKKYGGFDSPIVAYSILVIADIEKGKSKKLKTVKALVGVTIME KMTFERDPVAFLERKGYRNVQEENIIKLPKYSLFKLENGRKRLLASARELQKGNEIVLPNHLGT LLYHAKNIHKVDEPKHLDYVDKHKDEFKELLDVVSNFSKKYTLAEGNLEKIKELYAQNNGEDLK ELASSFINLLTFTAIGAPATFKFFDKNIDRKRYTSTTEILNATLIHQSITGLYETRIDLNKLGG D SEQ ID NO: 324 MDKKYSIGLDIGTNSVGWAVITDEYKVPSKKFKVLGNTDRHSIKKNLIGALLFDSGETAEATRL KRTARRRYTRRKNRICYLQEIFSNEMAKVDDSFFHRLEESFLVEEDKKHERHPIFGNIVDEVAY HEKYPTIYHLRKKLVDSTDKADLRLIYLALAHMIKFRGHFLIEGDLNPDNSDVDKLFIQLVQTY NQLFEENPINASGVDAKAILSARLSKSRRLENLIAQLPGEKKNGLFGNLIALSLGLTPNFKSNF DLAEDAKLQLSKDTYDDDLDNLLAQIGDQYADLFLAAKNLSDAILLSDILRVNTEITKAPLSAS MIKRYDEHHQDLTLLKALVRQQLPEKYKEIFFDQSKNGYAGYIDGGASQEEFYKFIKPILEKMD GTEELLVKLNREDLLRKQRTFDNGSIPHQIHLGELHAILRRQEDFYPFLKDNREKIEKILTFRI PYYVGPLARGNSRFAWMTRKSEETITPWNFEEVVDKGASAQSFIERMTNFDKNLPNEKVLPKHS LLYEYFTVYNELTKVKYVTEGMRKPAFLSGEQKKAIVDLLFKTNRKVTVKQLKEDYFKKIECFD SVEISGVEDRFNASLGTYHDLLKIIKDKDFLDNEENEDILEDIVLTLTLFEDREMIEERLKTYA HLFDDKVMKQLKRRRYTGWGRLSRKLINGIRDKQSGKTILDFLKSDGFANRNFMQLIHDDSLTF KEDIQKAQVSGQGDSLHEHIANLAGSPAIKKGILQTVKVVDELVKVMGRHKPENIVIEMARENQ TTQKGQKNSRERMKRIEEGIKELGSQILKEHPVENTQLQNEKLYLYYLQNGRDMYVDQELDINR LSDYDVDHIVPQSFLKDDSIDNKVLTRSDKNRGKSDNVPSEEVVKKMKNYWRQLLNAKLITQRK FDNLTKAERGGLSELDKAGFIKRQLVETRQITKHVAQILDSRMNTKYDENDKLIREVKVITLKS KLVSDFRKDFQFYKVREINNYHHAHDAYLNAVVGTALIKKYPKLESEFVYGDYKVYDVRKMIAK SEQEIGKATAKYFFYSNIMNFFKTEITLANGEIRKRPLIETNGETGEIVWDKGRDFATVRKVLS MPQVNIVKKTEVQTGGFSKESILPKRNSDKLIARKKDWDPKKYGGFDSPTVAYSVLVVAKVEKG KSKKLKSVKELLGITIMERSSFEKNPIDFLEAKGYKEVKKDLIIKLPKYSLFELENGRKRMLAS AGELQKGNELALPSKYVNFLYLASHYEKLKGSPEDNEQKQLFVEQHKHYLDEIIEQISEFSKRV ILADANLDKVLSAYNKHRDKPIREQAENIIHLFTLTNLGAPAAFKYFDTTIDRKRYTSTKEVLD ATLIHQSITGLYETRIDLSQLGGD SEQ ID NO: 325 MTKPYSIGLDIGTNSVGWAVTTDNYKVPSKKMKVLGNTSKKYIKKNLLGVLLFDSGITAEGRRL KRTARRRYTRRRNRILYLQEIFSTEMATLDDAFFQRLDDSFLVPDDKRDSKYPIFGNLVEEKAY HDEFPTIYHLRKYLADSTKKADLRLVYLALAHMIKYRGHFLIEGEFNSKNNDIQKNFQDFLDTY NAIFESDLSLENSKQLEEIVKDKISKLEKKDRILKLFPGEKNSGIFSEFLKLIVGNQADFRKCF NLDEKASLHFSKESYDEDLETLLGYIGDDYSDVFLKAKKLYDAILLSGFLTVTDNETEAPLSSA MIKRYNEHKEDLALLKEYIRNISLKTYNEVFKDDTKNGYAGYIDGKTNQEDFYVYLKKLLAEFE GADYFLEKIDREDFLRKQRTFDNGSIPYQIHLQEMRAILDKQAKFYPFLAKNKERIEKILTFRI PYYVGPLARGNSDFAWSIRKRNEKITPWNFEDVIDKESSAEAFINRMTSFDLYLPEEKVLPKHS LLYETFNVYNELTKVRFIAESMRDYQFLDSKQKKDIVRLYFKDKRKVTDKDIIEYLHAIYGYDG IELKGIEKQFNSSLSTYHDLLNIINDKEFLDDSSNEAIIEEIIHTLTIFEDREMIKQRLSKFEN IFDKSVLKKLSRRHYTGWGKLSAKLINGIRDEKSGNTILDYLIDDGISNRNFMQLIHDDALSFK KKIQKAQIIGDEDKGNIKEVVKSLPGSPAIKKGILQSIKIVDELVKVMGGRKPESIVVEMAREN QYTNQGKSNSQQRLKRLEKSLKELGSKILKENIPAKLSKIDNNALQNDRLYLYYLQNGKDMYTG DDLDIDRLSNYDIDHIIPQAFLKDNSIDNKVLVSSASNRGKSDDVPSLEVVKKRKTFWYQLLKS KLISQRKFDNLTKAERGGLSPEDKAGFIQRQLVETRQITKHVARLLDEKFNNKKDENNRAVRTV KIITLKSTLVSQFRKDFELYKVREINDFHHAHDAYLNAVVASALLKKYPKLEPEFVYGDYPKYN SFRERKSATEKVYFYSNIMNIFKKSISLADGRVIERPLIEVNEETGESVWNKESDLATVRRVLS YPQVNVVKKVEEQNHGLDRGKPKGLFNANLSSKPKPNSNENLVGAKEYLDPKKYGGYAGISNSF TVLVKGTIEKGAKKKITNVLEFQGISILDRINYRKDKLNFLLEKGYKDIELIIELPKYSLFELS DGSRRMLASILSTNNKRGEIHKGNQIFLSQKFVKLLYHAKRISNTINENHRKYVENHKKEFEEL FYYILEFNENYVGAKKNGKLLNSAFQSWQNHSIDELCSSFIGPTGSERKGLFELTSRGSAADFE FLGVKIPRYRDYTPSSLLKDATLIHQSVTGLYETRIDLAKLGEG SEQ ID NO: 326 MKKQKFSDYYLGFDIGTNSVGWCVTDLDYNVLRFNKKDMWGSRLFDEAKTAAERRVQRNSRRRL KRRKWRLNLLEEIFSDEIMKIDSNFFRRLKESSLWLEDKNSKEKFTLFNDDNYKDYDFYKQYPT IFHLRDELIKNPEKKDIRLIYLALHSIFKSRGHFLFEGQNLKEIKNFETLYNNLISFLEDNGIN KSIDKDNIEKLEKIICDSGKGLKDKEKEFKGIFNSDKQLVAIFKLSVGSSVSLNDLFDTDEYKK EEVEKEKISFREQIYEDDKPIYYSILGEKIELLDIAKSFYDFMVLNNILSDSNYISEAKVKLYE EHKKDLKNLKYIIRKYNKENYDKLFKDKNENNYPAYIGLNKEKDKKEVVEKSRLKIDDLIKVIK GYLPKPERIEEKDKTIFNEILNKIELKTILPKQRISDNGTLPYQIHEVELEKILENQSKYYDFL NYEENGVSTKDKLLKTFKFRIPYYVGPLNSYHKDKGGNSWIVRKEEGKILPWNFEQKVDIEKSA EEFIKRMTNKCTYLNGEDVIPKDSFLYSEYIILNELNKVQVNDEFLNEENKRKIIDELFKENKK VSEKKFKEYLLVNQIANRTVELKGIKDSFNSNYVSYIKFKDIFGEKLNLDIYKEISEKSILWKC LYGDDKKIFEKKIKNEYGDILNKDEIKKINSFKFNTWGRLSEKLLTGIEFINLETGECYSSVME ALRRTNYNLMELLSSKFTLQESIDNENKEMNEVSYRDLIEESYVSPSLKRAILQTLKIYEEIKK ITGRVPKKVFIEMARGGDESMKNKKIPARQEQLKKLYDSCGNDIANFSIDIKEMKNSLSSYDNN SLRQKKLYLYYLQFGKCMYTGREIDLDRLLQNNDTYDIDHIYPRSKVIKDDSFDNLVLVLKNEN AEKSNEYPVKKEIQEKMKSFWRFLKEKNFISDEKYKRLTGKDDFELRGFMARQLVNVRQTTKEV GKILQQIEPEIKIVYSKAEIASSFREMFDFIKVRELNDTHHAKDAYLNIVAGNVYNTKFTEKPY RYLQEIKENYDVKKIYNYDIKNAWDKENSLEIVKKNMEKNTVNITRFIKEEKGELFNLNPIKKG ETSNEIISIKPKLYDGKDNKLNEKYGYYTSLKAAYFIYVEHEKKNKKVKTFERITRIDSTLIKN EKNLIKYLVSQKKLLNPKIIKKIYKEQTLIIDSYPYTFTGVDSNKKVELKNKKQLYLEKKYEQI LKNALKFVEDNQGETEENYKFIYLKKRNNNEKNETIDAVKERYNIEFNEMYDKFLEKLSSKDYK NYINNKLYTNFLNSKEKFKKLKLWEKSLILREFLKIFNKNTYGKYEIKDSQTKEKLFSFPEDTG RIRLGQSSLGNNKELLEESVTGLFVKKIKL SEQ ID NO: 327 MKNYTIGLDIGVASVGWVCIDENYKILNYNNRHAFGVHEEESAESAAGRRLKRGMRRRYNRRKK RLQLLQSLFDSYITDSGFFSKTDSQHFWKNNNEFENRSLTEVLSSLRISSRKYPTIYHLRSDLI ESNKKMDLRLVYLALHNLVKYRGHFLQEGNWSEAASAEGMDDQLLELVTRYAELENLSPLDLSE SQWKAAETLLLNRNLTKTDQSKELTAMFGKEYEPFCKLVAGLGVSLHQLFPSSEQALAYKETKT KVQLSNENVEEVMELLLEEESALLEAVQPFYQQVVLYELLKGETYVAKAKVSAFKQYQKDMASL KNLLDKTFGEKVYRSYFISDKNSQREYQKSHKVEVLCKLDQFNKEAKFAETFYKDLKKLLEDKS KTSIGTTEKDEMLRIIKAIDSNQFLQKQKGIQNAAIPHQNSLYEAEKILRNQQAHYPFITTEWI EKVKQILAFRIPYYIGPLVKDTTQSPFSWVERKGDAPITPWNFDEQIDKAASAEAFISRMRKTC TYLKGQEVLPKSSLTYERFEVLNELNGIQLRTTGAESDFRHRLSYEMKCWIIDNVFKQYKTVST KRLLQELKKSPYADELYDEHTGEIKEVFGTQKENAFATSLSGYISMKSILGAVVDDNPAMTEEL IYWIAVFEDREILHLKIQEKYPSITDVQRQKLALVKLPGWGRFSRLLIDGLPLDEQGQSVLDHM EQYSSVFMEVLKNKGFGLEKKIQKMNQHQVDGTKKIRYEDIEELAGSPALKRGIWRSVKIVEEL VSIFGEPANIVLEVAREDGEKKRTKSRKDQWEELTKTTLKNDPDLKSFIGEIKSQGDORFNEQR FWLYVTQQGKCLYTGKALDIQNLSMYEVDHILPQNFVKDDSLDNLALVMPEANQRKNQVGQNKM PLEIIEANQQYAMRTLWERLHELKLISSGKLGRLKKPSFDEVDKDKFIARQLVETRQIIKHVRD LLDERFSKSDIHLVKAGIVSKFRRFSEIPKIRDYNNKHHAMDALFAAALIQSILGKYGKNFLAF DLSKKDRQKQWRSVKGSNKEFFLFKNFGNLRLQSPVTGEEVSGVEYMKHVYFELPWQTTKMTQT GDGMFYKESIFSPKVKQAKYVSPKTEKFVHDEVKNHSICLVEFTFMKKEKEVQETKEIDLKVIE HHQFLKEPESQLAKFLAEKETNSPIIHARIIRTIPKYQKIWIEHFPYYFISTRELHNARQFEIS YELMEKVKQLSERSSVEELKIVFGLLIDQMNDNYPIYTKSSIQDRVQKFVDTQLYDFKSFEIGF EELKKAVAANAQRSDTFGSRISKKPKPEEVAIGYESITGLKYRKPRSVVGTKR SEQ ID NO: 328 MKKEIKDYFLGLDVGTGSVGWAVTDTDYKLLKANRKDLWGMRCFETAETAEVRRLHRGARRRIE RRKKRIKLLQELFSQEIAKTDEGFFQRMKESPFYAEDKTILQENTLFNDKDFADKTYHKAYPTI NHLIKAWIENKVKPDPRLLYLACHNIIKKRGHFLFEGDFDSENQFDTSIQALFEYLREDMEVDI DADSQKVKEILKDSSLKNSEKQSRLNKILGLKPSDKQKKAITNLISGNKINFADLYDNPDLKDA EKNSISFSKDDFDALSDDLASILGDSFELLLKAKAVYNCSVLSKVIGDEQYLSFAKVKIYEKHK TDLTKLKNVIKKHFPKDYKKVFGYNKNEKNNNNYSGYVGVCKTKSKKLIINNSVNQEDFYKFLK TILSAKSEIKEVNDILTEIETGTFLPKQISKSNAEIPYQLRKMELEKILSNAEKHFSFLKQKDE KGLSHSEKIIMLLTFKIPYYIGPINDNHKKFFPDRCWVVKKEKSPSGKTTPWNFFDHIDKEKTA EAFITSRTNFCTYLVGESVLPKSSLLYSEYTVLNEINNLQIIIDGKNICDIKLKQKIYEDLFKK YKKITQKQISTFIKHEGICNKTDEVIILGIDKECTSSLKSYIELKNIFGKQVDEISTKNMLEEI IRWATIYDEGEGKTILKTKIKAEYGKYCSDEQIKKILNLKFSGWGRLSRKFLETVTSEMPGFSE PVNIITAMRETQNNLMELLSSEFTFTENIKKINSGFEDAEKQFSYDGLVKPLFLSPSVKKMLWQ TLKLVKEISHITQAPPKKIFIEMAKGAELEPARTKTRLKILQDLYNNCKNDADAFSSEIKDLSG KIENEDNLRLRSDKLYLYYTQLGKCMYCGKPIEIGHVFDTSNYDIDHIYPQSKIKDDSISNRVL VCSSCNKNKEDKYPLKSEIQSKQRGFWNFLQRNNFISLEKLNRLTRATPISDDETAKFIARQLV ETRQATKVAAKVLEKMFPETKIVYSKAETVSMFRNKFDIVKCREINDFHHAHDAYLNIVVGNVY NTKFTNNPWNFIKEKRDNPKIADTYNYYKVFDYDVKRNNITAWEKGKTIITVKDMLKRNTPIYT RQAACKKGELFNQTIMKKGLGQHPLKKEGPFSNISKYGGYNKVSAAYYTLIEYEEKGNKIRSLE TIPLYLVKDIQKDQDVLKSYLTDLLGKKEFKILVPKIKINSLLKINGFPCHITGKTNDSFLLRP AVQFCCSNNEVLYFKKIIRFSEIRSQREKIGKTISPYEDLSFRSYIKENLWKKTKNDEIGEKEF YDLLQKKNLEIYDMLLTKHKDTIYKKRPNSATIDILVKGKEKFKSLIIENQFEVILEILKLFSA TRNVSDLQHIGGSKYSGVAKIGNKISSLDNCILIYQSITGIFEKRIDLLKV SEQ ID NO: 329 MEGQMKNNGNNLQQGNYYLGLDVGTSSVGWAVTDTDYNVLKFRGKSMWGARLFDEASTAEERRT HRGNRRRLARRKYRLLLLEQLFEKEIRKIDDNFFVRLHESNLWADDKSKPSKFLLFNDTNFTDK DYLKKYPTIYHLRSDLIHNSTEHDIRLVFLALHHLIKYRGHFIYDNSANGDVKTLDEAVSDFEE YLNENDIEFNIENKKEFINVLSDKHLTKKEKKISLKKLYGDITDSENINISVLIEMLSGSSISL SNLFKDIEFDGKQNLSLDSDIEETLNDVVDILGDNIDLLIHAKEVYDIAVLTSSLGKHKYLCDA KVELFEKNKKDLMILKKYIKKNHPEDYKKIFSSPTEKKNYAAYSQTNSKNVCSQEEFCLFIKPY IRDMVKSENEDEVRIAKEVEDKSFLTKLKGTNNSVVPYQIHERELNQILKNIVAYLPFMNDEQE DISVVDKIKLIFKFKIPYYVGPLNTKSTRSWVYRSDEKIYPWNFSNVIDLDKTAHEFMNRLIGR CTYTNDPVLPMDSLLYSKYNVLNEINPIKVNGKAIPVEVKQAIYTDLFENSKKKVTRKSIYIYL LKNGYIEKEDIVSGIDIEIKSKLKSHHDFTQIVQENKCTPEEIERIIKGILVYSDDKSMLRRWL KNNIKGLSENDVKYLAKLNYKEWGRLSKTLLTDIYTINPEDGEACSILDIMWNTNATLMEILSN EKYQFKQNIENYKAENYDEKQNLHEELDDMYISPAARRSIWQALRIVDEIVDIKKSAPKKIFIE MAREKKSAMKKKRTESRKDTLLELYKSCKSQADGFYDEELFEKLSNESNSRLRRDQLYLYYTOM GRSMYTGKRIDFDKLINDKNTYDIDHIYPRSKIKDDSITNRVLVEKDINGEKTDIYPISEDIRQ KMQPFWKILKEKGLINEEKYKRLTRNYELTDEELSSFVARQLVETQQSTKALATLLKKEYPSAK IVYSKAGNVSEFRNRKDKELPKFREINDLHHAKDAYLNIVVGNVYDTKFTEKFFNNIRNENYSL KRVFDFSVPGAWDAKGSTFNTIKKYMAKNNPIIAFAPYEVKGELFDQQIVPKGKGQFPIKQGKD IEKYGGYNKLSSAFLFAVEYKGKKARERSLETVYIKDVELYLQDPIKYCESVLGLKEPQIIKPK ILMGSLFSINNKKLVVTGRSGKQYVCHHIYQLSINDEDSQYLKNIAKYLQEEPDGNIERQNILN ITSVNNIKLFDVLCTKFNSNTYEIILNSLKNDVNEGREKFSELDILEQCNILLQLLKAFKCNRE SSNLEKLNNKKQAGVIVIPHLFTKCSVFKVIHQSITGLFEKEMDLLK SEQ ID NO: 330 MGRKPYILSLDIGTGSVGYACMDKGFNVLKYHDKDALGVYLFDGALTAQERRQFRTSRRRKNRR IKRLGLLQELLAPLVQNPNFYQFQRQFAWKNDNMDFKNKSLSEVLSFLGYESKKYPTIYHLQEA LLLKDEKFDPELIYMALYHLVKYRGHFLFDHLKIENLTNNDNMHDFVELIETYENLNNIKLNLD YEKTKVIYEILKDNEMTKNDRAKRVKNMEKKLEQFSIMLLGLKFNEGKLFNHADNAEELKGANQ SHTFADNYEENLTPFLTVEQSEFIERANKIYLSLTLQDILKGKKSMAMSKVAAYDKFRNELKQV KDIVYKADSTRTQFKKIFVSSKKSLKQYDATPNDQTFSSLCLFDQYLIRPKKQYSLLIKELKKI IPQDSELYFEAENDTLLKVLNTTDNASIPMQINLYEAETILRNQQKYHAEITDEMIEKVLSLIQ FRIPYYVGPLVNDHTASKFGWMERKSNESIKPWNFDEVVDRSKSATQFIRRMTNKCSYLINEDV LPKNSLLYQEMEVLNELNATQIRLQTDPKNRKYRMMPQIKLFAVEHIFKKYKTVSHSKFLEIML NSNHRENFMNHGEKLSIFGTQDDKKFASKLSSYQDMTKIFGDIEGKRAQIEEIIQWITIFEDKK ILVQKLKECYPELTSKQINQLKKLNYSGWGRLSEKLLTHAYQGHSIIELLRHSDENFMEILTND VYGFQNFIKEENQVQSNKIQHQDIANLTTSPALKKGIWSTIKLVRELTSIFGEPEKIIMEFATE DQQKGKKQKSRKQLWDDNIKKNKLKSVDEYKYIIDVANKLNNEQLQQEKLWLYLSQNGKCMYSG QSIDLDALLSPNATKHYEVDHIFPRSFIKDDSIDNKVLVIKKMNQTKGDQVPLQFIQQPYERIA YWKSLNKAGLISDSKLHKLMKPEFTAMDKEGFIQRQLVETRQISVHVRDFLKEEYPNTKVIPMK AKMVSEFRKKFDIPKIRQMNDAHHAIDAYLNGVVYHGAQLAYPNVDLFDFNFKWEKVREKWKAL GEFNTKQKSRELFFFKKLEKMEVSQGERLISKIKLDMNHFKINYSRKLANIPQQFYNQTAVSPK TAELKYESNKSNEVVYKGLTPYQTYVVAIKSVNKKGKEKMEYQMIDHYVFDFYKFQNGNEKELA LYLAQRENKDEVLDAQIVYSLNKGDLLYINNHPCYFVSRKEVINAKQFELTVEQQLSLYNVMNN KETNVEKLLIEYDFIAEKVINEYHHYLNSKLKEKRVRTFFSESNQTHEDFIKALDELFKVVTAS ATRSDKIGSRKNSMTHRAFLGKGKDVKIAYTSISGLKTTKPKSLFKLAESRNEL SEQ ID NO: 331 MAKILGLDLGTNSIGWAVVERENIDFSLIDKGVRIFSEGVKSEKGIESSRAAERTGYRSARKIK YRRKLRKYETLKVLSLNRMCPLSIEEVEEWKKSGFKDYPLNPEFLKWLSTDEESNVNPYFFRDR ASKHKVSLFELGRAFYHIAQRRGFLSNRLDQSAEGILEEHCPKIEAIVEDLISIDEISTNITDY FFETGILDSNEKNGYAKDLDEGDKKLVSLYKSLLAILKKNESDFENCKSEIIERLNKKDVLGKV KGKIKDISQAMLDGNYKTLGQYFYSLYSKEKIRNQYTSREEHYLSEFITICKVQGIDQINEEEK INEKKFDGLAKDLYKAIFFQRPLKSQKGLIGKCSFEKSKSRCAISHPDFEEYRMWTYLNTIKIG TQSDKKLRFLTQDEKLKLVPKFYRKNDFNFDVLAKELIEKGSSFGFYKSSKKNDFFYWFNYKPT DTVAACQVAASLKNAIGEDWKTKSFKYQTINSNKEQVSRTVDYKDLWHLLTVATSDVYLYEFAI DKLGLDEKNAKAFSKTKLKKDFASLSLSAINKILPYLKEGLLYSHAVFVANIENIVDENIWKDE KQRDYIKTQISEIIENYTLEKSRFEIINGLLKEYKSENEDGKRVYYSKEAEQSFENDLKKKLVL FYKSNEIENKEQQETIFNELLPIFIQQLKDYEFIKIQRLDQKVLIFLKGKNETGQIFCTEEKGT AEEKEKKIKNRLKKLYHPSDIEKFKKKIIKDEFGNEKIVLGSPLTPSIKNPMAMRALHQLRKVL NALILEGQIDEKTIIHIEMARELNDANKRKGIQDYQNDNKKFREDAIKEIKKLYFEDCKKEVEP TEDDILRYQLWMEQNRSEIYEEGKNISICDIIGSNPAYDIEHTIPRSRSQDNSQMNKTLCSQRF NREVKKQSMPIELNNHLEILPRIAHWKEEADNLTREIEIISRSIKAAATKEIKDKKIRRRHYLT LKRDYLQGKYDRFIWEEPKVGFKNSQIPDTGIITKYAQAYLKSYFKKVESVKGGMVAEFRKIWG IQESFIDENGMKHYKVKDRSKHTHHTIDAITIACMTKEKYDVLAHAWTLEDQQNKKEARSIIEA SKPWKTFKEDLLKIEEEILVSHYTPDNVKKQAKKIVRVRGKKQFVAEVERDVNGKAVPKKAASG KTIYKLDGEGKKLPRLQQGDTIRGSLHQDSIYGAIKNPLNTDEIKYVIRKDLESIKGSDVESIV DEVVKEKIKEAIANKVLLLSSNAQQKNKLVGTVWMNEEKRIAINKVRIYANSVKNPLHIKEHSL LSKSKHVHKQKVYGQNDENYAMAIYELDGKRDFELINIFNLAKLIKQGQGFYPLHKKKEIKGKI VFVPIEKRNKRDVVLKRGQQVVFYDKEVENPKDISEIVDFKGRIYIIEGLSIQRIVRPSGKVDE YGVIMLRYFKEARKADDIKQDNFKPDGVFKLGENKPTRKMNHQFTAFVEGIDFKVLPSGKFEKI SEQ ID NO: 332 MEFKKVLGLDIGTNSIGCALLSLPKSIQDYGKGGRLEWLTSRVIPLDADYMKAFIDGKNGLPQV ITPAGKRRQKRGSRRLKHRYKLRRSRLIRVFKTLNWLPEDFPLDNPKRIKETISTEGKESERIS DYVPISDESYREFYREFGYPENEIEQVIEEINFRRKTKGKNKNPMIKLLPEDWVVYYLRKKALI KPTTKEELIRIIYLFNQRRGFKSSRKDLTETAILDYDEFAKRLAEKEKYSAENYETKFVSITKV KEVVELKTDGRKGKKRFKVILEDSRIEPYEIERKEKPDWEGKEYTFLVTQKLEKGKFKQNKPDL PKEEDWALCTTALDNRMGSKHPGEFFFDELLKAFKEKRGYKIRQYPVNRWRYKKELEFIWTKQC QLNPELNNLNINKEILRKLATVLYPSQSKFFGPKIKEFENSDVLHIISEDIIYYQRDLKSQKSL ISECRYEKRKGIDGEIYGLKCIPKSSPLYQEFRIWQDIHNIKVIRKESEVNGKKKINIDETQLY INENIKEKLFELFNSKDSLSEKDILELISLNIINSGIKISKKEEETTHRINLFANRKELKGNET KSRYRKVFKKLGFDGEYILNHPSKLNRLWHSDYSNDYADKEKTEKSILSSLGWKNRNGKWEKSK NYDVFNLPLEVAKAIANLPPLKKEYGSYSALAIRKMLVVMRDGKYWQHPDQIAKDQENTSLMLE DKNLIQLTNNQRKVLNKYLLTLAEVQKRSTLIKQKLNEIEHNPYKLELVSDQDLEKQVLKSFLE KKNESDYLKGLKTYQAGYLIYGKHSEKDVPIVNSPDELGEYIRKKLPNNSLRNPIVEQVIRETI FIVRDVWKSFGIIDEIHIELGRELKNNSEERKKTSESQEKNFQEKERARKLLKELLNSSNFEHY DENGNKIFSSFTVNPNPDSPLDIEKFRIWKNQSGLTDEELNKKLKDEKIPTEIEVKKYILWLTQ KCRSPYTGKIIPLSKLFDSNVYEIEHIIPRSKMKNDSTNNLVICELGVNKAKGDRLAANFISES NGKCKFGEVEYTLLKYGDYLQYCKDTFKYQKAKYKNLLATEPPEDFIERQINDTRYIGRKLAEL LTPVVKDSKNIIFTIGSITSELKITWGLNGVWKDILRPRFKRLESIINKKLIFQDEDDPNKYHF DLSINPQLDKEGLKRLDHRHHALDATIIAATTREHVRYLNSLNAADNDEEKREYFLSLCNHKIR DFKLPWENFTSEVKSKLLSCVVSYKESKPILSDPFNKYLKWEYKNGKWQKVFAIQIKNDRWKAV RRSMFKEPIGTVWIKKIKEVSLKEAIKIQAIWEEVKNDPVRKKKEKYIYDDYAQKVIAKIVQEL GLSSSMRKQDDEKLNKFINEAKVSAGVNKNLNTTNKTIYNLEGRFYEKIKVAEYVLYKAKRMPL NKKEYIEKLSLQKMFNDLPNFILEKSILDNYPEILKELESDNKYIIEPHKKNNPVNRLLLEHIL EYHNNPKEAFSTEGLEKLNKKAINKIGKPIKYITRLDGDINEEEIFRGAVFETDKGSNVYFVMY ENNQTKDREFLKPNPSISVLKAIEHKNKIDFFAPNRLGFSRIILSPGDLVYVPTNDQYVLIKDN SSNETIINWDDNEFISNRIYQVKKFTGNSCYFLKNDIASLILSYSASNGVGEFGSQNISEYSVD DPPIRIKDVCIKIRVDRLGNVRPL SEQ ID NO: 333 MKHILGLDLGTNSIGWALIERNIEEKYGKIIGMGSRIVPMGAELSKFEQGQAQTKNADRRTNRG ARRLNKRYKQRRNKLIYILQKLDMLPSQIKLKEDFSDPNKIDKITILPISKKQEQLTAFDLVSL RVKALTEKVGLEDLGKIIYKYNQLRGYAGGSLEPEKEDIFDEEQSKDKKNKSFIAFSKIVFLGE PQEEIFKNKKLNRRAIIVETEEGNFEGSTFLENIKVGDSLELLINISASKSGDTITIKLPNKTN WRKKMENIENQLKEKSKEMGREFYISEFLLELLKENRWAKIRNNTILRARYESEFEAIWNEQVK HYPFLENLDKKTLIEIVSFIFPGEKESQKKYRELGLEKGLKYIIKNQVVFYQRELKDQSHLISD CRYEPNEKAIAKSHPVFQEYKVWEQINKLIVNTKIEAGTNRKGEKKYKYIDRPIPTALKEWIFE ELQNKKEITFSAIFKKLKAEFDLREGIDFLNGMSPKDKLKGNETKLQLQKSLGELWDVLGLDSI NRQIELWNILYNEKGNEYDLTSDRTSKVLEFINKYGNNIVDDNAEETAIRISKIKFARAYSSLS LKAVERILPLVRAGKYFNNDFSQQLQSKILKLLNENVEDPFAKAAQTYLDNNQSVLSEGGVGNS IATILVYDKHTAKEYSHDELYKSYKEINLLKQGDLRNPLVEQIINEALVLIRDIWKNYGIKPNE IRVELARDLKNSAKERATIHKRNKDNQTINNKIKETLVKNKKELSLANIEKVKLWEAQRHLSPY TGQPIPLSDLFDKEKYDVDHIIPISRYEDDSFTNKVISEKSVNQEKANRTAMEYFEVGSLKYSI FTKEQFIAHVNEYFSGVKRKNLLATSIPEDPVQRQIKDTQYIAIRVKEELNKIVGNENVKTTTG SITDYLRNHWGLTDKFKLLLKERYEALLESEKFLEAEYDNYKKDFDSRKKEYEEKEVLFEEQEL TREEFIKEYKENYIRYKKNKLIIKGWSKRIDHRHHAIDALIVACTEPAHIKRLNDLNKVLQDWL VEHKSEFMPNFEGSNSELLEEILSLPENERTEIFTQIEKFRAIEMPWKGFPEQVEQKLKEIIIS HKPKDKLLLQYNKAGDRQIKLRGQLHEGTLYGISQGKEAYRIPLTKFGGSKFATEKNIQKIVSP FLSGFIANHLKEYNNKKEEAFSAEGIMDLNNKLAQYRNEKGELKPHTPISTVKIYYKDPSKNKK KKDEEDLSLQKLDREKAFNEKLYVKTGDNYLFAVLEGEIKTKKTSQIKRLYDIISFFDATNFLK EEFRNAPDKKTFDKDLLFRQYFEERNKAKLLFTLKQGDFVYLPNENEEVILDKESPLYNQYWGD LKERGKNIYVVQKFSKKQIYFIKHTIADIIKKDVEFGSQNCYETVEGRSIKENCFKLEIDRLGN IVKVIKR SEQ ID NO: 334 MHVEIDFPHFSRGDSHLAMNKNEILRGSSVLYRLGLDLGSNSLGWFVTHLEKRGDRHEPVALGP GGVRIFPDGRDPQSGTSNAVDRRMARGARKRRDRFVERRKELIAALIKYNLLPDDARERRALEV LDPYALRKTALTDTLPAHHVGRALFHLNQRRGFQSNRKTDSKQSEDGAIKQAASRLATDKGNET LGVFFADMHLRKSYEDRQTAIRAELVRLGKDHLTGNARKKIWAKVRKRLFGDEVLPRADAPHGV RARATITGTKASYDYYPTRDMLRDEFNAIWAGQSAHHATITDEARTEIEHIIFYQRPLKPAIVG KCTLDPATRPFKEDPEGYRAPWSHPLAQRFRILSEARNLEIRDTGKGSRRLTKEQSDLVVAALL ANREVKFDKLRTLLKLPAEARFNLESDRRAALDGDQTAARLSDKKGFNKAWRGFPPERQIAIVA RLEETEDENELIAWLEKECALDGAAAARVANTTLPDGHCRLGLRAIKKIVPIMQDGLDEDGVAG AGYHIAAKRAGYDHAKLPTGEQLGRLPYYGQWLQDAVVGSGDARDQKEKQYGQFPNPTVHIGLG QLRRVVNDLIDKYGPPTEISIEFTRALKLSEQQKAERQREQRRNQDKNKARAEELAKFGRPANP RNLLKMRLWEELAHDPLDRKCVYTGEQISIERLLSDEVDIDHILPVAMTLDDSPANKIICMRYA NRHKRKQTPSEAFGSSPTLQGHRYNWDDIAARATGLPRNKRWRFDANAREEFDKRGGFLARQLN ETGWLARLAKQYLGAVTDPNQIWVVPGRLTSMLRGKWGLNGLLPSDNYAGVQDKAEEFLASTDD MEFSGVKNRADHRHHAIDGLVTALTDRSLLWKMANAYDEEHEKFVIEPPWPTMRDDLKAALEKM VVSHKPDHGIEGKLHEDSAYGFVKPLDATGLKEEEAGNLVYRKAIESLNENEVDRIRDIQLRTI VRDHVNVEKTKGVALADALRQLQAPSDDYPQFKHGLRHVRILKKEKGDYLVPIANRASGVAYKA YSAGENFCVEVFETAGGKWDGEAVRRFDANKKNAGPKIAHAPQWRDANEGAKLVMRIHKGDLIR LDHEGRARIMVVHRLDAAAGRFKLADHNETGNLDKRHATNNDIDPFRWLMASYNTLKKLAAVPV RVDELGRVWRVMPN SEQ ID NO: 335 METTLGIDLGTNSIGLALVDQEEHQILYSGVRIFPEGINKDTIGLGEKEESRNATRRAKRQMRR QYFRKKLRKAKLLELLIAYDMCPLKPEDVRRWKNWDKQQKSTVRQFPDTPAFREWLKQNPYELR KQAVTEDVTRPELGRILYQMIQRRGFLSSRKGKEEGKIFTGKDRMVGIDETRKNLQKQTLGAYL YDIAPKNGEKYRFRTERVRARYTLRDMYIREFEIIWQRQAGHLGLAHEQATRKKNIFLEGSATN VRNSKLITHLQAKYGRGHVLIEDTRITVTFQLPLKEVLGGKIEIEEEQLKFKSNESVLFWQRPL RSQKSLLSKCVFEGRNFYDPVHQKWIIAGPTPAPLSHPEFEEFRAYQFINNIIYGKNEHLTAIQ REAVFELMCTESKDFNFEKIPKHLKLFEKFNFDDTTKVPACTTISQLRKLFPHPVWEEKREEIW HCFYFYDDNTLLFEKLQKDYALQTNDLEKIKKIRLSESYGNVSLKAIRRINPYLKKGYAYSTAV LLGGIRNSFGKRFEYFKEYEPEIEKAVCRILKEKNAEGEVIRKIKDYLVHNRFGFAKNDRAFQK LYHHSQAITTQAQKERLPETGNLRNPIVQQGLNELRRTVNKLLATCREKYGPSFKFDHIHVEMG RELRSSKTEREKQSRQIRENEKKNEAAKVKLAEYGLKAYRDNIQKYLLYKEIEEKGGTVCCPYT GKTLNISHTLGSDNSVQIEHIIPYSISLDDSLANKTLCDATFNREKGELTPYDFYQKDPSPEKW GASSWEEIEDRAFRLLPYAKAQRFIRRKPQESNEFISRQLNDTRYISKKAVEYLSAICSDVKAF PGQLTAELRHLWGLNNILQSAPDITFPLPVSATENHREYYVITNEQNEVIRLFPKQGETPRTEK GELLLTGEVERKVFRCKGMQEFQTDVSDGKYWRRIKLSSSVTWSPLFAPKPISADGQIVLKGRI EKGVFVCNQLKQKLKTGLPDGSYWISLPVISQTFKEGESVNNSKLTSQQVQLFGRVREGIFRCH NYQCPASGADGNFWCTLDTDTAQPAFTPIKNAPPGVGGGQIILTGDVDDKGIFHADDDLHYELP ASLPKGKYYGIFTVESCDPTLIPIELSAPKTSKGENLIEGNIWVDEHTGEVRFDPKKNREDQRH HAIDAIVIALSSQSLFQRLSTYNARRENKKRGLDSTEHFPSPWPGFAQDVRQSVVPLLVSYKQN PKTLCKISKTLYKDGKKIHSCGNAVRGQLHKETVYGQRTAPGATEKSYHIRKDIRELKTSKHIG KVVDITIRQMLLKHLQENYHIDITQEFNIPSNAFFKEGVYRIFLPNKHGEPVPIKKIRMKEELG NAERLKDNINQYVNPRNNHHVMIYQDADGNLKEEIVSFWSVIERQNQGQPIYQLPREGRNIVSI LQINDTFLIGLKEEEPEVYRNDLSTLSKHLYRVQKLSGMYYTFRHHLASTLNNEREEFRIQSLE AWKRANPVKVQIDEIGRITFLNGPLC SEQ ID NO: 336 MESSQILSPIGIDLGGKFTGVCLSHLEAFAELPNHANTKYSVILIDHNNFQLSQAQRRATRHRV RNKKRNQFVKRVALQLFQHILSRDLNAKEETALCHYLNNRGYTYVDTDLDEYIKDETTINLLKE LLPSESEHNFIDWFLQKMQSSEFRKILVSKVEEKKDDKELKNAVKNIKNFITGFEKNSVEGHRH RKVYFENIKSDITKDNQLDSIKKKIPSVCLSNLLGHLSNLQWKNLHRYLAKNPKQFDEQTFGNE FLRMLKNFRHLKGSQESLAVRNLIQQLEQSQDYISILEKTPPEITIPPYEARTNTGMEKDQSLL LNPEKLNNLYPNWRNLIPGIIDAHPFLEKDLEHTKLRDRKRIISPSKQDEKRDSYILQRYLDLN KKIDKFKIKKQLSFLGQGKQLPANLIETQKEMETHFNSSLVSVLIQIASAYNKEREDAAQGIWF DNAFSLCELSNINPPRKQKILPLLVGAILSEDFINNKDKWAKFKIFWNTHKIGRTSLKSKCKEI EEARKNSGNAFKIDYEEALNHPEHSNNKALIKIIQTIPDIIQAIQSHLGHNDSQALIYHNPFSL SQLYTILETKRDGFHKNCVAVTCENYWRSQKTEIDPEISYASRLPADSVRPFDGVLARMMQRLA YEIAMAKWEQIKHIPDNSSLLIPIYLEQNRFEFEESFKKIKGSSSDKTLEQAIEKQNIQWEEKF QRIINASMNICPYKGASIGGQGEIDHIYPRSLSKKHFGVIFNSEVNLIYCSSQGNREKKEEHYL LEHLSPLYLKHQFGTDNVSDIKNFISQNVANIKKYISFHLLTPEQQKAARHALFLDYDDEAFKT ITKFLMSQQKARVNGTQKFLGKQIMEFLSTLADSKQLQLEFSIKQITAEEVHDHRELLSKQEPK LVKSRQQSFPSHAIDATLTMSIGLKEFPQFSQELDNSWFINHLMPDEVHLNPVRSKEKYNKPNI SSTPLFKDSLYAERFIPVWVKGETFAIGFSEKDLFEIKPSNKEKLFTLLKTYSTKNPGESLQEL QAKSKAKWLYFPINKTLALEFLHHYFHKEIVTPDDTTVCHFINSLRYYTKKESITVKILKEPMP VLSVKFESSKKNVLGSFKHTIALPATKDWERLFNHPNFLALKANPAPNPKEFNEFIRKYFLSDN NPNSDIPNNGHNIKPQKHKAVRKVFSLPVIPGNAGTMMRIRRKDNKGQPLYQLQTIDDTPSMGI QINEDRLVKQEVLMDAYKTRNLSTIDGINNSEGQAYATFDNWLTLPVSTFKPEIIKLEMKPHSK TRRYIRITQSLADFIKTIDEALMIKPSDSIDDPLNMPNEIVCKNKLFGNELKPRDGKMKIVSTG KIVTYEFESDSTPQWIQTLYVTQLKKQP SEQ ID NO: 337 MKKIVGLDLGTNSIGWALINAYINKEHLYGIEACGSRIIPMDAAILGNFDKGNSISQTADRTSY RGIRRLRERHLLRRERLHRILDLLGFLPKHYSDSLNRYGKFLNDIECKLPWVKDETGSYKFIFQ ESFKEMLANFTEHHPILIANNKKVPYDWTIYYLRKKALTQKISKEELAWILLNFNQKRGYYQLR GEEEETPNKLVEYYSLKVEKVEDSGERKGKDTWYNVHLENGMIYRRTSNIPLDWEGKTKEFIVT TDLEADGSPKKDKEGNIKRSFRAPKDDDWTLIKKKTEADIDKIKMTVGAYIYDTLLQKPDQKIR GKLVRTIERKYYKNELYQILKTQSEFHEELRDKQLYIACLNELYPNNEPRRNSISTRDFCHLFI EDIIFYQRPLKSKKSLIDNCPYEENRYIDKESGEIKHASIKCIAKSHPLYQEFRLWQFIVNLRI YRKETDVDVTQELLPTEADYVTLFEWLNEKKEIDQKAFFKYPPFGFKKTTSNYRWNYVEDKPYP CNETHAQIIARLGKAHIPKAFLSKEKEETLWHILYSIEDKQEIEKALHSFANKNNLSEEFIEQF KNEPPEKKEYGSYSAKAIKKLLPLMRMGKYWSIENIDNGTRIRINKIIDGEYDENIRERVRQKA INLTDITHFRALPLWLACYLVYDRHSEVKDIVKWKTPKDIDLYLKSFKQHSLRNPIVEQVITET LRTVRDIWQQVGHIDEIHIELGREMKNPADKRARMSQQMIKNENTNLRIKALLTEFLNPEFGIE NVRPYSPSQQDLLRIYEEGVLNSILELPEDIGIILGKFNQTDTLKRPTRSEILRYKLWLEQKYR SPYTGEMIPLSKLFTPAYEIEHIIPQSRYFDDSLSNKVICESEINKLKDRSLGYEFIKNHHGEK VELAFDKPVEVLSVEAYEKLVHESYSHNRSKMKKLLMEDIPDQFIERQLNDSRYISKVVKSLLS NIVREENEQEAISKNVIPCTGGITDRLKKDWGINDVWNKIVLPRFIRLNELTESTRFTSINTNN TMIPSMPLELQKGFNKKRIDHRHHAMDAIIIACANRNIVNYLNNVSASKNTKITRRDLQTLLCH KDKTDNNGNYKWVIDKPWETFTQDTLTALQKITVSFKQNLRVINKTTNHYQHYENGKKIVSNQS KGDSWAIRKSMHKETVHGEVNLRMIKTVSFNEALKKPQAIVEMDLKKKILAMLELGYDTKRIKN YFEENKDTWQDINPSKIKVYYFTKETKDRYFAVRKPIDTSFDKKKIKESITDTGIQQIMLRHLE TKDNDPTLAFSPDGIDEMNRNILILNKGKKHQPIYKVRVYEKAEKFTVGQKGNKRTKFVEAAKG TNLFFAIYETEEIDKDTKKVIRKRSYSTIPLNVVIERQKQGLSSAPEDENGNLPKYILSPNDLV YVPTQEEINKGEVVMPIDRDRIYKMVDSSGITANFIPASTANLIFALPKATAEIYCNGENCIQN EYGIGSPQSKNQKAITGEMVKEICFPIKVDRLGNIIQVGSCILTN SEQ ID NO: 338 MSRSLTFSFDIGYASIGWAVIASASHDDADPSVCGCGTVLFPKDDCQAFKRREYRRLRRNIRSR RVRIERIGRLLVQAQIITPEMKETSGHPAPFYLASEALKGHRTLAPIELWHVLRWYAHNRGYDN NASWSNSLSEDGGNGEDTERVKHAQDLMDKHGTATMAETICRELKLEEGKADAPMEVSTPAYKN LNTAFPRLIVEKEVRRILELSAPLIPGLTAEIIELIAQHHPLTTEQRGVLLQHGIKLARRYRGS LLFGQLIPRFDNRIISRCPVTWAQVYEAELKKGNSEQSARERAEKLSKVPTANCPEFYEYRMAR ILCNIRADGEPLSAEIRRELMNQARQEGKLTKASLEKAISSRLGKETETNVSNYFTLHPDSEEA LYLNPAVEVLQRSGIGQILSPSVYRIAANRLRRGKSVTPNYLLNLLKSRGESGEALEKKIEKES KKKEADYADTPLKPKYATGRAPYARTVLKKVVEEILDGEDPTRPARGEAHPDGELKAHDGCLYC LLDTDSSVNQHQKERRLDTMTNNHLVRHRMLILDRLLKDLIQDFADGQKDRISRVCVEVGKELT TFSAMDSKKIQRELTLRQKSHTDAVNRLKRKLPGKALSANLIRKCRIAMDMNWTCPFTGATYGD HELENLELEHIVPHSFRQSNALSSLVLTWPGVNRMKGQRTGYDFVEQEQENPVPDKPNLHICSL NNYRELVEKLDDKKGHEDDRRRKKKRKALLMVRGLSHKHQSQNHEAMKEIGMTEGMMTQSSHLM KLACKSIKTSLPDAHIDMIPGAVTAEVRKAWDVFGVFKELCPEAADPDSGKILKENLRSLTHLH HALDACVLGLIPYIIPAHHNGLLRRVLAMRRIPEKLIPQVRPVANQRHYVLNDDGRMMLRDLSA SLKENIREQLMEQRVIQHVPADMGGALLKETMQRVLSVDGSGEDAMVSLSKKKDGKKEKNQVKA SKLVGVFPEGPSKLKALKAAIEIDGNYGVALDPKPVVIRHIKVFKRIMALKEQNGGKPVRILKK GMLIHLTSSKDPKHAGVWRIESIQDSKGGVKLDLQRAHCAVPKNKTHECNWREVDLISLLKKYQ MKRYPTSYTGTPR SEQ ID NO: 339 MTQKVLGLDLGTNSIGSAVRNLDLSDDLQWQLEFFSSDIFRSSVNKESNGREYSLAAQRSAHRR SRGLNEVRRRRLWATLNLLIKHGFCPMSSESLMRWCTYDKRKGLFREYPIDDKDFNAWILLDFN GDGRPDYSSPYQLRRELVTRQFDFEQPIERYKLGRALYHIAQHRGFKSSKGETLSQQETNSKPS STDEIPDVAGAMKASEEKLSKGLSTYMKEHNLLTVGAAFAQLEDEGVRVRNNNDYRAIRSQFQH EIETIFKFQQGLSVESELYERLISEKKNVGTIFYKRPLRSQRGNVGKCTLERSKPRCAIGHPLF EKFRAWTLINNIKVRMSVDTLDEQLPMKLRLDLYNECFLAFVRTEFKFEDIRKYLEKRLGIHFS YNDKTINYKDSTSVAGCPITARFRKMLGEEWESFRVEGQKERQAHSKNNISFHRVSYSIEDIWH FCYDAEEPEAVLAFAQETLRLERKKAEELVRIWSAMPQGYAMLSQKAIRNINKILMLGLKYSDA VILAKVPELVDVSDEELLSIAKDYYLVEAQVNYDKRINSIVNGLIAKYKSVSEEYRFADHNYEY LLDESDEKDIIRQIENSLGARRWSLMDANEQTDILQKVRDRYQDFFRSHERKFVESPKLGESFE NYLTKKFPMVEREQWKKLYHPSQITIYRPVSVGKDRSVLRLGNPDIGAIKNPTVLRVLNTLRRR VNQLLDDGVISPDETRVVVETARELNDANRKWALDTYNRIRHDENEKIKKILEEFYPKRDGIST DDIDKARYVIDQREVDYFTGSKTYNKDIKKYKFWLEQGGQCMYTGRTINLSNLFDPNAFDIEHT IPESLSFDSSDMNLTLCDAHYNRFIKKNHIPTDMPNYDKAITIDGKEYPAITSQLQRWVERVER LNRNVEYWKGQARRAQNKDRKDQCMREMHLWKMELEYWKKKLERFTVTEVTDGFKNSQLVDTRV ITRHAVLYLKSIFPHVDVQRGDVTAKFRKILGIQSVDEKKDRSLHSHHAIDATTLTIIPVSAKR DRMLELFAKIEEINKMLSFSGSEDRTGLIQELEGLKNKLQMEVKVCRIGHNVSEIGTFINDNII VNHHIKNQALTPVRRRLRKKGYIVGGVDNPRWQTGDALRGEIHKASYYGAITQFAKDDEGKVLM KEGRPQVNPTIKFVIRRELKYKKSAADSGFASWDDLGKAIVDKELFALMKGQFPAETSFKDACE QGIYMIKKGKNGMPDIKLHHIRHVRCEAPQSGLKIKEQTYKSEKEYKRYFYAAVGDLYAMCCYT NGKIREFRIYSLYDVSCHRKSDIEDIPEFITDKKGNRLMLDYKLRTGDMILLYKDNPAELYDLD NVNLSRRLYKINRFESQSNLVLMTHHLSTSKERGRSLGKTVDYQNLPESIRSSVKSLNFLIMGE NRDFVIKNGKIIFNHR SEQ ID NO: 340 MLVSPISVDLGGKNTGFFSFTDSLDNSQSGTVIYDESFVLSQVGRRSKRHSKRNNLRNKLVKRL FLLILQEHHGLSIDVLPDEIRGLFNKRGYTYAGFELDEKKKDALESDTLKEFLSEKLQSIDRDS DVEDFLNQIASNAESFKDYKKGFEAVFASATHSPNKKLELKDELKSEYGENAKELLAGLRVTKE ILDEFDKQENQGNLPRAKYFEELGEYIATNEKVKSFFDSNSLKLTDMTKLIGNISNYQLKELRR YFNDKEMEKGDIWIPNKLHKITERFVRSWHPKNDADRQRRAELMKDLKSKEIMELLTTTEPVMT IPPYDDMNNRGAVKCQTLRLNEEYLDKHLPNWRDIAKRLNHGKFNDDLADSTVKGYSEDSTLLH RLLDTSKEIDIYELRGKKPNELLVKTLGQSDANRLYGFAQNYYELIRQKVRAGIWVPVKNKDDS LNLEDNSNMLKRCNHNPPHKKNQIHNLVAGILGVKLDEAKFAEFEKELWSAKVGNKKLSAYCKN IEELRKTHGNTFKIDIEELRKKDPAELSKEEKAKLRLTDDVILNEWSQKIANFFDIDDKHRQRF NNLFSMAQLHTVIDTPRSGFSSTCKRCTAENRFRSETAFYNDETGEFHKKATATCQRLPADTQR PFSGKIERYIDKLGYELAKIKAKELEGMEAKEIKVPIILEQNAFEYEESLRKSKTGSNDRVINS KKDRDGKKLAKAKENAEDRLKDKDKRIKAFSSGICPYCGDTIGDDGEIDHILPRSHTLKIYGTV FNPEGNLIYVHQKCNQAKADSIYKLSDIKAGVSAQWIEEQVANIKGYKTFSVLSAEQQKAFRYA LFLQNDNEAYKKVVDWLRTDQSARVNGTQKYLAKKIQEKLTKMLPNKHLSFEFILADATEVSEL RRQYARQNPLLAKAEKQAPSSHAIDAVMAFVARYQKVFKDGTPPNADEVAKLAMLDSWNPASNE PLTKGLSTNQKIEKMIKSGDYGQKNMREVFGKSIFGENAIGERYKPIVVQEGGYYIGYPATVKK GYELKNCKVVTSKNDIAKLEKIIKNQDLISLKENQYIKIFSINKQTISELSNRYFNMNYKNLVE RDKEIVGLLEFIVENCRYYTKKVDVKFAPKYIHETKYPFYDDWRRFDEAWRYLQENQNKTSSKD RFVIDKSSLNEYYQPDKNEYKLDVDTQPIWDDFCRWYFLDRYKTANDKKSIRIKARKTFSLLAE SGVQGKVFRAKRKIPTGYAYQALPMDNNVIAGDYANILLEANSKTLSLVPKSGISIEKQLDKKL DVIKKTDVRGLAIDNNSFFNADFDTHGIRLIVENTSVKVGNFPISAIDKSAKRMIFRALFEKEK GKRKKKTTISFKESGPVQDYLKVFLKKIVKIQLRTDGSISNIVVRKNAADFTLSFRSEHIQKLL K SEQ ID NO: 341 MAYRLGLDIGITSVGWAVVALEKDESGLKPVRIQDLGVRIFDKAEDSKTGASLALPRREARSAR RRTRRRRHRLWRVKRLLEQHGILSMEQIEALYAQRTSSPDVYALRVAGLDRCLIAEEIARVLIH IAHRRGFQSNRKSEIKDSDAGKLLKAVQENENLMQSKGYRTVAEMLVSEATKTDAEGKLVHGKK HGYVSNVRNKAGEYRHTVSRQAIVDEVRKIFAAQRALGNDVMSEELEDSYLKILCSQRNFDDGP GGDSPYGHGSVSPDGVRQSIYERMVGSCTFETGEKRAPRSSYSFERFQLLTKVVNLRIYRQQED GGRYPCELTQTERARVIDCAYEQTKITYGKLRKLLDMKDTESFAGLTYGLNRSRNKTEDTVFVE MKFYHEVRKALQRAGVFIQDLSIETLDQIGWILSVWKSDDNRRKKLSTLGLSDNVIEELLPLNG SKFGHLSLKAIRKILPFLEDGYSYDVACELAGYQFQGKTEYVKQRLLPPLGEGEVTNPVVRRAL SQAIKVVNAVIRKHGSPESIHIELARELSKNLDERRKIEKAQKENQKNNEQIKDEIREILGSAH VTGRDIVKYKLFKQQQEFCMYSGEKLDVTRLFEPGYAEVDHIIPYGISFDDSYDNKVLVKTEQN RQKGNRTPLEYLRDKPEQKAKFIALVESIPLSQKKKNHLLMDKRAIDLEQEGFRERNLSDTRYI TRALMNHIQAWLLFDETASTRSKRVVCVNGAVTAYMRARWGLTKDRDAGDKHHAADAVVVACIG DSLIQRVTKYDKFKRNALADRNRYVQQVSKSEGITQYVDKETGEVFTWESFDERKFLPNEPLEP WPFFRDELLARLSDDPSKNIRAIGLLTYSETEQIDPIFVSRMPTRKVTGAAHKETIRSPRIVKV DDNKGTEIQVVVSKVALTELKLTKDGEIKDYFRPEDDPRLYNTLRERLVQFGGDAKAAFKEPVY KISKDGSVRTPVRKVKIQEKLTLGVPVHGGRGIAENGGMVRIDVFAKGGKYYFVPIYVADVLKR ELPNRLATAHKPYSEWRVVDDSYQFKFSLYPNDAVMIKPSREVDITYKDRKEPVGCRIMYFVSA NIASASISLRTHDNSGELEGLGIQGLEVFEKYVVGPLGDTHPVYKERRMPFRVERKMN SEQ ID NO: 342 MPVLSPLSPNAAQGRRRWSLALDIGEGSIGWAVAEVDAEGRVLQLTGTGVTLFPSAWSNENGTY VAHGAADRAVRGQQQRHDSRRRRLAGLARLCAPVLERSPEDLKDLTRTPPKADPRAIFFLRADA ARRPLDGPELFRVLHHMAAHRGIRLAELQEVDPPPESDADDAAPAATEDEDGTRRAAADERAFR RLMAEHMHRHGTQPTCGEIMAGRLRETPAGAQPVTRARDGLRVGGGVAVPTRALIEQEFDAIRA IQAPRHPDLPWDSLRRLVLDQAPIAVPPATPCLFLEELRRRGETFQGRTITREAIDRGLTVDPL IQALRIRETVGNLRLHERITEPDGRQRYVPRAMPELGLSHGELTAPERDTLVRALMHDPDGLAA KDGRIPYTRLRKLIGYDNSPVCFAQERDTSGGGITVNPTDPLMARWIDGWVDLPLKARSLYVRD VVARGADSAALARLLAEGAHGVPPVAAAAVPAATAAILESDIMQPGRYSVCPWAAEAILDAWAN APTEGFYDVTRGLFGFAPGEIVLEDLRRARGALLAHLPRTMAAARTPNRAAQQRGPLPAYESVI PSQLITSLRRAHKGRAADWSAADPEERNPFLRTWTGNAATDHILNQVRKTANEVITKYGNRRGW DPLPSRITVELAREAKHGVIRRNEIAKENRENEGRRKKESAALDTFCQDNTVSWQAGGLPKERA ALRLRLAQRQEFFCPYCAERPKLRATDLFSPAETEIDHVIERRMGGDGPDNLVLAHKDCNNAKG KKTPHEHAGDLLDSPALAALWQGWRKENADRLKGKGHKARTPREDKDFMDRVGWRFEEDARAKA EENQERRGRRMLHDTARATRLARLYLAAAVMPEDPAEIGAPPVETPPSPEDPTGYTAIYRTISR VQPVNGSVTHMLRQRLLQRDKNRDYQTHHAEDACLLLLAGPAVVQAFNTEAAQHGADAPDDRPV DLMPTSDAYHQQRRARALGRVPLATVDAALADIVMPESDRQDPETGRVHWRLTRAGRGLKRRID DLTRNCVILSRPRRPSETGTPGALHNATHYGRREITVDGRTDTVVTQRMNARDLVALLDNAKIV PAARLDAAAPGDTILKEIGTEIADRHDRVVDPEGTHARRWISARLAALVPAHAEAVARDIAELA DLDALADADRTPEQEARRSALRQSPYLGRAISAKKADGRARAREQEILTRALLDPHWGPRGLRH LIMREARAPSLVRIRANKTDAFGRPVPDAAVWVKTDGNAVSQLWRLTSVVTDDGRRIPLPKPIE KRIEISNLEYARLNGLDEGAGVTGNNAPPRPLRQDIDRLTPLWRDHGTAPGGYLGTAVGELEDK ARSALRGKAMRQTLTDAGITAEAGWRLDSEGAVCDLEVAKGDTVKKDGKTYKVGVITQGIFGMP VDAAGSAPRTPEDCEKFEEQYGIKPWKAKGIPLA SEQ ID NO: 343 MNYTEKEKLFMKYILALDIGIASVGWAILDKESETVIEAGSNIFPEASAADNQLRRDMRGAKRN NRRLKTRINDFIKLWENNNLSIPQFKSTEIVGLKVRAITEEITLDELYLILYSYLKHRGISYLE DALDDTVSGSSAYANGLKLNAKELETHYPCEIQQERLNTIGKYRGQSQIINENGEVLDLSNVFT IGAYRKEIQRVFEIQKKYHPELTDEFCDGYMLIFNRKRKYYEGPGNEKSRTDYGRFTTKLDANG NYITEDNIFEKLIGKCSVYPDELRAAAASYTAQEYNVLNDLNNLTINGRKLEENEKHEIVERIK SSNTINMRKIISDCMGENIDDFAGARIDKSGKEIFHKFEVYNKMRKALLEIGIDISNYSREELD EIGYIMTINTDKEAMMEAFQKSWIDLSDDVKQCLINMRKTNGALFNKWQSFSLKIMNELIPEMY AQPKEQMTLLTEMGVTKGTQEEFAGLKYIPVDVVSEDIFNPVVRRSVRISFKILNAVLKKYKAL DTIVIEMPRDRNSEEQKKRINDSQKLNEKEMEYIEKKLAVTYGIKLSPSDFSSQKQLSLKLKLW NEQDGICLYSGKTIDPNDIINNPQLFEIDHIIPRSISFDDARSNKVLVYRSENQKKGNQTPYYY LTHSHSEWSFEQYKATVMNLSKKKEYAISRKKIQNLLYSEDITKMDVLKGFINRNINDTSYASR LVLNTIQNFFMANEADTKVKVIKGSYTHQMRCNLKLDKNRDESYSHHAVDAMLIGYSELGYEAY HKLQGEFIDFETGEILRKDMWDENMSDEVYADYLYGKKWANIRNEVVKAEKNVKYWHYVMRKSN RGLCNQTIRGTREYDGKQYKINKLDIRTKEGIKVFAKLAFSKKDSDRERLLVYLNDRRTFDDLC KIYEDYSDAANPFVQYEKETGDIIRKYSKKHNGPRIDKLKYKDGEVGACIDISHKYGFEKGSKK VILESLVPYRMDVYYKEENHSYYLVGVKQSDIKFEKGRNVIDEEAYARILVNEKMIQPGQSRAD LENLGFKFKLSFYKNDIIEYEKDGKIYTERLVSRTMPKQRNYIETKPIDKAKFEKQNLVGLGKT KFIKKYRYDILGNKYSCSEEKFTSFC SEQ ID NO: 344 MLRLYCANNLVLNNVQNLWKYLLLLIFDKKIIFLFKIKVILIRRYMENNNKEKIVIGFDLGVAS VGWSIVNAETKEVIDLGVRLFSEPEKADYRRAKRTTRRLLRRKKFKREKFHKLILKNAEIFGLQ SRNEILNVYKDQSSKYRNILKLKINALKEEIKPSELVWILRDYLQNRGYFYKNEKLTDEFVSNS FPSKKLHEHYEKYGFFRGSVKLDNKLDNKKDKAKEKDEEEESDAKKESEELIFSNKQWINEIVK VFENQSYLTESFKEEYLKLFNYVRPFNKGPGSKNSRTAYGVFSTDIDPETNKFKDYSNIWDKTI GKCSLFEEEIRAPKNLPSALIFNLQNEICTIKNEFTEFKNWWLNAEQKSEILKFVFTELFNWKD KKYSDKKFNKNLQDKIKKYLLNFALENFNLNEEILKNRDLENDTVLGLKGVKYYEKSNATADAA LEFSSLKPLYVFIKFLKEKKLDLNYLLGLENTEILYFLDSIYLAISYSSDLKERNEWFKKLLKE LYPKIKNNNLEIIENVEDIFEITDQEKFESFSKTHSLSREAFNHIIPLLLSNNEGKNYESLKHS NEELKKRTEKAELKAQQNQKYLKDNFLKEALVPLSVKTSVLQAIKIFNQIIKNFGKKYEISQVV IEMARELTKPNLEKLLNNATNSNIKILKEKLDQTEKFDDFTKKKFIDKIENSVVFRNKLFLWFE QDRKDPYTQLDIKINEIEDETEIDHVIPYSKSADDSWFNKLLVKKSTNQLKKNKTVWEYYQNES DPEAKWNKFVAWAKRIYLVQKSDKESKDNSEKNSIFKNKKPNLKFKNITKKLFDPYKDLGFLAR NLNDTRYATKVFRDQLNNYSKHHSKDDENKLFKVVCMNGSITSFLRKSMWRKNEEQVYRFNFWK KDRDQFFHHAVDASIIAIFSLLTKTLYNKLRVYESYDVQRREDGVYLINKETGEVKKADKDYWK DQHNFLKIRENAIEIKNVLNNVDFQNQVRYSRKANTKLNTQLFNETLYGVKEFENNFYKLEKVN LFSRKDLRKFILEDLNEESEKNKKNENGSRKRILTEKYIVDEILQILENEEFKDSKSDINALNK YMDSLPSKFSEFFSQDFINKCKKENSLILTFDAIKHNDPKKVIKIKNLKFFREDATLKNKQAVH KDSKNQIKSFYESYKCVGFIWLKNKNDLEESIFVPINSRVIHFGDKDKDIFDEDSYNKEKLLNE INLKRPENKKFNSINEIEFVKFVKPGALLLNFENQQIYYISTLESSSLRAKIKLLNKMDKGKAV SMKKITNPDEYKIIEHVNPLGINLNWTKKLENNN SEQ ID NO: 345 MLMSKHVLGLDLGVGSIGWCLIALDAQGDPAEILGMGSRVVPLNNATKAIEAFNAGAAFTASQE RTARRTMRRGFARYQLRRYRLRRELEKVGMLPDAALIQLPLLELWELRERAATAGRRLTLPELG RVLCHINQKRGYRHVKSDAAAIVGDEGEKKKDSNSAYLAGIRANDEKLQAEHKTVGQYFAEQLR QNQSESPTGGISYRIKDQIFSRQCYIDEYDQIMAVQRVHYPDILTDEFIRMLRDEVIEMQRPLK SCKHLVSLCEFEKQERVMRVQQDDGKGGWQLVERRVKFGPKVAPKSSPLFQLCCIYEAVNNIRL TRPNGSPCDITPEERAKIVAHLQSSASLSFAALKKLLKEKALIADQLTSKSGLKGNSTRVALAS ALQPYPQYHHLLDMELETRMMTVQLTDEETGEVTEREVAVVTDSYVRKPLYRLWHILYSIEERE AMRRALITQLGMKEEDLDGGLLDQLYRLDFVKPGYGNKSAKFICKLLPQLQQGLGYSEACAAVG YRHSNSPTSEEITERTLLEKIPLLQRNELRQPLVEKILNQMINLVNALKAEYGIDEVRVELARE LKMSREERERMARNNKDREERNKGVAAKIRECGLYPTKPRIQKYMLWKEAGRQCLYCGRSIEEE QCLREGGMEVEHIIPKSVLYDDSYGNKTCACRRCNKEKGNRTALEYIRAKGREAEYMKRINDLL KEKKISYSKHQRLRWLKEDIPSDFLERQLRLTQYISRQAMAILQQGIRRVSASEGGVTARLRSL WGYGKILHTLNLDRYDSMGETERVSREGEATEELHITNWSKRMDHRHHAIDALVVACTRQSYIQ RLNRLSSEFGREDKKKEDQEAQEQQATETGRLSNLERWLTQRPHFSVRTVSDKVAEILISYRPG QRVVTRGRNIYRKKMADGREVSCVQRGVLVPRGELMEASFYGKILSQGRVRIVKRYPLHDLKGE VVDPHLRELITTYNQELKSREKGAPIPPLCLDKDKKQEVRSVRCYAKTLSLDKAIPMCFDEKGE PTAFVKSASNHHLALYRTPKGKLVESIVTFWDAVDRARYGIPLVITHPREVMEQVLQRGDIPEQ VLSLLPPSDWVFVDSLQQDEMVVIGLSDEELQRALEAQNYRKISEHLYRVQKMSSSYYVFRYHL ETSVADDKNTSGRIPKFHRVQSLKAYEERNIRKVRVDLLGRISLL SEQ ID NO: 346 MSDLVLGLDIGIGSVGVGILNKVTGEIIHKNSRIFPAAQAENNLVRRTNRQGRRLARRKKHRRV RLNRLFEESGLITDFTKISINLNPYQLRVKGLTDELSNEELFIALKNMVKHRGISYLDDASDDG NSSVGDYAQIVKENSKQLETKTPGQIQLERYQTYGQLRGDFTVEKDGKKHRLINVFPTSAYRSE ALRILQTQQEFNPQITDEFINRYLEILTGKRKYYHGPGNEKSRTDYGRYRTSGETLDNIFGILI GKCTFYPDEFRAAKASYTAQEFNLLNDLNNLTVPTETKKLSKEQKNQIINYVKNEKAMGPAKLF KYIAKLLSCDVADIKGYRIDKSGKAEIHTFEAYRKMKTLETLDIEQMDRETLDKLAYVLTLNTE REGIQEALEHEFADGSFSQKQVDELVQFRKANSSIFGKGWHNFSVKLMMELIPELYETSEEQMT ILTRLGKQKTTSSSNKTKYIDEKLLTEEIYNPVVAKSVRQAIKIVNAAIKEYGDFDNIVIEMAR ETNEDDEKKAIQKIQKANKDEKDAAMLKAANQYNGKAELPHSVFHGHKQLATKIRLWHQQGERC LYTGKTISIHDLINNSNQFEVDHILPLSITFDDSLANKVLVYATANQEKGQRTPYQALDSMDDA WSFRELKAFVRESKTLSNKKKEYLLTEEDISKFDVRKKFIERNLVDTRYASRVVLNALQEHFRA HKIDTKVSVVRGQFTSQLRRHWGIEKTRDTYHHHAVDALIIAASSQLNLWKKQKNTLVSYSEDQ LLDIETGELISDDEYKESVFKAPYQHFVDTLKSKEFEDSILFSYQVDSKFNRKISDATIYATRQ AKVGKDKADETYVLGKIKDIYTQDGYDAFMKIYKKDKSKFLMYRHDPQTFEKVIEPILENYPNK QINEKGKEVPCNPFLKYKEEHGYIRKYSKKGNGPEIKSLKYYDSKLGNHIDITPKDSNNKVVLQ SVSPWRADVYFNKTTGKYEILGLKYADLQFEKGTGTYKISQEKYNDIKKKEGVDSDSEFKFTLY KNDLLLVKDTETKEQQLFRFLSRTMPKQKHYVELKPYDKQKFEGGEALIKVLGNVANSGQCKKG LGKSNISIYKVRTDVLGNQHIIKNEGDKPKLDF SEQ ID NO: 347 MNAEHGKEGLLIMEENFQYRIGLDIGITSVGWAVLQNNSQDEPVRITDLGVRIFDVAENPKNGD ALAAPRRDARTTRRRLRRRRHRLERIKFLLQENGLIEMDSFMERYYKGNLPDVYQLRYEGLDRK LKDEELAQVLIHIAKHRGFRSTRKAETKEKEGGAVLKATTENQKIMQEKGYRTVGEMLYLDEAF HTECLWNEKGYVLTPRNRPDDYKHTILRSMLVEEVHAIFAAQRAHGNQKATEGLEEAYVEIMTS QRSFDMGPGLQPDGKPSPYAMEGFGDRVGKCTFEKDEYRAPKATYTAELFVALQKINHTKLIDE FGTGRFFSEEERKTIIGLLLSSKELKYGTIRKKLNIDPSLKFNSLNYSAKKEGETEEERVLDTE KAKFASMFWTYEYSKCLKDRTEEMPVGEKADLFDRIGEILTAYKNDDSRSSRLKELGLSGEEID GLLDLSPAKYQRVSLKAMRKMQPYLEDGLIYDKACEAAGYDFRALNDGNKKHLLKGEEINAIVN DITNPVVKRSVSQTIKVINAIIQKYGSPOAVNIELAREMSKNFODRTNLEKEMKKROQENERAK QQIIELGKQNPTGQDILKYRLWNDQGGYCLYSGKKIPLEELFDGGYDIDHILPYSITFDDSYRN KVLVTAQENRQKGNRTPYEYFGADEKRWEDYEASVRLLVRDYKKQQKLLKKNFTEEERKEFKER NLNDTKYITRVVYNMIRQNLELEPFNHPEKKKQVWAVNGAVTSYLRKRWGLMQKDRSTDRHHAM DAVVIACCTDGMIHKISRYMQGRELAYSRNFKFPDEETGEILNRDNFTREQWDEKFGVKVPLPW NSFRDELDIRLLNEDPKNFLLTHADVQRELDYPGWMYGEEESPIEEGRYINYIRPLFVSRMPNH KVTGSAHDATIRSARDYETRGVVITKVPLTDLKLNKDNEIEGYYDKDSDRLLYQALVRQLLLHG NDGKKAFAEDFHKPKADGTEGPVVRKVKIEKKQTSGVMVRGGTGIAANGEMVRIDVFRENGKYY FVPVYTADVVRKVLPNRAATHTKPYSEWRVMDDANFVFSLYSRDLIHVKSKKDIKTNLVNGGLL LQKEIFAYYTGADIATASIAGFANDSNFKFRGLGIQSLEIFEKCQVDILGNISVVRHENRQEFH SEQ ID NO: 348 MRVLGLDAGIASLGWALIEIEESNRGELSQGTIIGAGTWMFDAPEEKTQAGAKLKSEQRRTFRG QRRVVRRRRQRMNEVRRILHSHGLLPSSDRDALKQPGLDPWRIRAEALDRLLGPVELAVALGHI ARHRGFKSNSKGAKTNDPADDTSKMKRAVNETREKLARFGSAAKMLVEDESFVLRQTPTKNGAS EIVRRFRNREGDYSRSLLRDDLAAEMRALFTAQARFQSAIATADLQTAFTKAAFFQRPLQDSEK LVGPCPFEVDEKRAPKRGYSFELFRFLSRLNHVTLRDGKQERTLTRDELALAAADFGAAAKVSF TALRKKLKLPETTVFVGVKADEESKLDVVARSGKAAEGTARLRSVIVDALGELAWGALLCSPEK LDKIAEVISFRSDIGRISEGLAQAGCNAPLVDALTAAASDGRFDPFTGAGHISSKAARNILSGL RQGMTYDKACCAADYDHTASRERGAFDVGGHGREALKRILQEERISRELVGSPTARKALIESIK QVKAIVERYGVPDRIHVELARDVGKSIEEREEITRGIEKRNRQKDKLRGLFEKEVGRPPQDGAR GKEELLRFELWSEQMGRCLYTDDYISPSQLVATDDAVQVDHILPWSRFADDSYANKTLCMAKAN QDKKGRTPYEWFKAEKTDTEWDAFIVRVEALADMKGFKKRNYKLRNAEEAAAKFRNRNLNDTRW ACRLLAEALKQLYPKGEKDKDGKERRRVFSRPGALTDRLRRAWGLQWMKKSTKGDRIPDDRHHA LDAIVIAATTESLLQRATREVQEIEDKGLHYDLVKNVTPPWPGFREQAVEAVEKVFVARAERRR ARGKAHDATIRHIAVREGEQRVYERRKVAELKLADLDRVKDAERNARLIEKLRNWIEAGSPKDD PPLSPKGDPIFKVRLVTKSKVNIALDTGNPKRPGTVDRGEMARVDVFRKASKKGKYEYYLVPIY PHDIATMKTPPIRAVQAYKPEDEWPEMDSSYEFCWSLVPMTYLQVISSKGEIFEGYYRGMNRSV GAIQLSAHSNSSDVVQGIGARTLTEFKKFNVDRFGRKHEVERELRTWRGETWRGKAYI SEQ ID NO: 349 MGNYYLGLDVGIGSIGWAVINIEKKRIEDFNVRIFKSGEIQEKNRNSRASQQCRRSRGLRRLYR RKSHRKLRLKNYLSIIGLTTSEKIDYYYETADNNVIQLRNKGLSEKLTPEEIAACLIHICNNRG YKDFYEVNVEDIEDPDERNEYKEEHDSIVLISNLMNEGGYCTPAEMICNCREFDEPNSVYRKFH NSAASKNHYLITRHMLVKEVDLILENQSKYYGILDDKTIAKIKDIIFAQRDFEIGPGKNERFRR FTGYLDSIGKCQFFKDQERGSRFTVIADIYAFVNVLSQYTYTNNRGESVFDTSFANDLINSALK NGSMDKRELKAIAKSYHIDISDKNSDTSLTKCFKYIKVVKPLFEKYGYDWDKLIENYTDTDNNV LNRIGIVLSQAQTPKRRREKLKALNIGLDDGLINELTKLKLSGTANVSYKYMQGSIEAFCEGDL YGKYQAKFNKEIPDIDENAKPQKLPPFKNEDDCEFFKNPVVFRSINETRKLINAIIDKYGYPAA VNIETADELNKTFEDRAIDTKRNNDNQKENDRIVKEIIECIKCDEVHARHLIEKYKLWEAQEGK CLYSGETITKEDMLRDKDKLFEVDHIVPYSLILDNTINNKALVYAEENQKKGQRTPLMYMNEAQ AADYRVRVNTMFKSKKCSKKKYQYLMLPDLNDQELLGGWRSRNLNDTRYICKYLVNYLRKNLRF DRSYESSDEDDLKIRDHYRVFPVKSRFTSMFRRWWLNEKTWGRYDKAELKKLTYLDHAADAIII ANCRPEYVVLAGEKLKLNKMYHQAGKRITPEYEQSKKACIDNLYKLFRMDRRTAEKLLSGHGRL TPIIPNLSEEVDKRLWDKNIYEQFWKDDKDKKSCEELYRENVASLYKGDPKFASSLSMPVISLK PDHKYRGTITGEEAIRVKEIDGKLIKLKRKSISEITAESINSIYTDDKILIDSLKTIFEQADYK DVGDYLKKTNQHFFTTSSGKRVNKVTVIEKVPSRWLRKEIDDNNFSLLNDSSYYCIELYKDSKG DNNLQGIAMSDIVHDRKTKKLYLKPDFNYPDDYYTHVMYIFPGDYLRIKSTSKKSGEQLKFEGY FISVKNVNENSFRFISDNKPCAKDKRVSITKKDIVIKLAVDLMGKVQGENNGKGISCGEPLSLL KEKN SEQ ID NO: 350 MLSRQLLGASHLARPVSYSYNVQDNDVHCSYGERCFMRGKRYRIGIDVGLNSVGLAAVEVSDEN SPVRLLNAQSVIHDGGVDPQKNKEAITRKNMSGVARRTRRMRRRKRERLHKLDMLLGKFGYPVI EPESLDKPFEEWHVRAELATRYIEDDELRRESISIALRHMARHRGWRNPYRQVDSLISDNPYSK QYGELKEKAKAYNDDATAAEEESTPAQLVVAMLDAGYAEAPRLRWRTGSKKPDAEGYLPVRLMQ EDNANELKQIFRVQRVPADEWKPLFRSVFYAVSPKGSAEQRVGQDPLAPEQARALKASLAFQEY RIANVITNLRIKDASAELRKLTVDEKQSIYDQLVSPSSEDITWSDLCDFLGFKRSQLKGVGSLT EDGEERISSRPPRLTSVQRIYESDNKIRKPLVAWWKSASDNEHEAMIRLLSNTVDIDKVREDVA YASAIEFIDGLDDDALTKLDSVDLPSGRAAYSVETLQKLTRQMLTTDDDLHEARKTLFNVTDSW RPPADPIGEPLGNPSVDRVLKNVNRYLMNCQQRWGNPVSVNIEHVRSSFSSVAFARKDKREYEK NNEKRSIFRSSLSEQLRADEQMEKVRESDLRRLEAIQRQNGQCLYCGRTITFRTCEMDHIVPRK GVGSTNTRTNFAAVCAECNRMKSNTPFAIWARSEDAQTRGVSLAEAKKRVTMFTFNPKSYAPRE VKAFKQAVIARLQQTEDDAAIDNRSIESVAWMADELHRRIDWYFNAKQYVNSASIDDAEAETMK TTVSVFQGRVTASARRAAGIEGKIHFIGQQSKTRLDRRHHAVDASVIAMMNTAAAQTLMERESL RESQRLIGLMPGERSWKEYPYEGTSRYESFHLWLDNMDVLLELLNDALDNDRIAVMQSQRYVLG NSIAHDATIHPLEKVPLGSAMSADLIRRASTPALWCALTRLPDYDEKEGLPEDSHREIRVHDTR YSADDEMGFFASQAAQIAVQEGSADIGSAIHHARVYRCWKTNAKGVRKYFYGMIRVFQTDLLRA CHDDLFTVPLPPQSISMRYGEPRVVQALQSGNAQYLGSLVVGDEIEMDFSSLDVDGQIGEYLQF FSQFSGGNLAWKHWVVDGFFNQTQLRIRPRYLAAEGLAKAFSDDVVPDGVQKIVTKQGWLPPVN TASKTAVRIVRRNAFGEPRLSSAHHMPCSWQWRHE SEQ ID NO: 351 MYSIGLDLGISSVGWSVIDERTGNVIDLGVRLFSAKNSEKNLERRTNRGGRRLIRRKTNRLKDA KKILAAVGFYEDKSLKNSCPYQLRVKGLTEPLSRGEIYKVTLHILKKRGISYLDEVDTEAAKES QDYKEQVRKNAQLLTKYTPGQIQLQRLKENNRVKTGINAQGNYQLNVFKVSAYANELATILKTQ QAFYPNELTDDWIALFVQPGIAEEAGLIYRKRPYYHGPGNEANNSPYGRWSDFQKTGEPATNIF DKLIGKDFQGELRASGLSLSAQQYNLLNDLTNLKIDGEVPLSSEQKEYILTELMTKEFTRFGVN DVVKLLGVKKERLSGWRLDKKGKPEIHTLKGYRNWRKIFAEAGIDLATLPTETIDCLAKVLTLN TEREGIENTLAFELPELSESVKLLVLDRYKELSQSISTQSWHRFSLKTLHLLIPELMNATSEQN TLLEQFQLKSDVRKRYSEYKKLPTKDVLAEIYNPTVNKTVSQAFKVIDALLVKYGKEQIRYITI EMPRDDNEEDEKKRIKELHAKNSQRKNDSQSYFMQKSGWSQEKFQTTIQKNRRFLAKLLYYYEQ DGICAYTGLPISPELLVSDSTEIDHIIPISISLDDSINNKVLVLSKANQVKGQQTPYDAWMDGS FKKINGKFSNWDDYQKWVESRHFSHKKENNLLETRNIFDSEQVEKFLARNLNDTRYASRLVLNT LQSFFTNQETKVRVVNGSFTHTLRKKWGADLDKTRETHHHHAVDATLCAVTSFVKVSRYHYAVK EETGEKVMREIDFETGEIVNEMSYWEFKKSKKYERKTYQVKWPNFREQLKPVNLHPRIKFSHQV DRKANRKLSDATIYSVREKTEVKTLKSGKQKITTDEYTIGKIKDIYTLDGWEAFKKKQDKLLMK DLDEKTYERLLSIAETTPDFQEVEEKNGKVKRVKRSPFAVYCEENDIPAIQKYAKKNNGPLIRS LKYYDGKLNKHINITKDSQGRPVEKTKNGRKVTLQSLKPYRYDIYQDLETKAYYTVQLYYSDLR FVEGKYGITEKEYMKKVAEQTKGQVVRFCFSLQKNDGLEIEWKDSQRYDVRFYNFQSANSINFK GLEQEMMPAENQFKQKPYNNGAINLNIAKYGKEGKKLRKFNTDILGKKHYLFYEKEPKNIIK SEQ ID NO: 352 MYFYKNKENKLNKKVVLGLDLGIASVGWCLTDISQKEDNKFPIILHGVRLFETVDDSDDKLLNE TRRKKRGQRRRNRRLFTRKRDFIKYLIDNNIIELEFDKNPKILVRNFIEKYINPFSKNLELKYK SVTNLPIGFHNLRKAAINEKYKLDKSELIVLLYEYLSLRGAFFDNPEDTKSKEMNKNEIEIEDK NESIKNAEFPIDKIIEFYKISGKIRSTINLKFGHQDYLKEIKQVFEKQNIDFMNYEKFAMEEKS FFSRIRNYSEGPGNEKSFSKYGLYANENGNPELIINEKGQKIYTKIFKTLWESKIGKCSYDKKL YRAPKNSFSAKVFDITNKLTDWKHKNEYISERLKRKILLSRFLNKDSKSAVEKILKEENIKFEN LSEIAYNKDDNKINLPIINAYHSLTTIFKKHLINFENYLISNENDLSKLMSFYKQQSEKLFVPN EKGSYEINQNNNVLHIFDAISNILNKFSTIQDRIRILEGYFEFSNLKKDVKSSEIYSEIAKLRE FSGTSSLSFGAYYKFIPNLISEGSKNYSTISYEEKALQNQKNNFSHSNLFEKTWVEDLIASPTV KRSLRQTMNLLKEIFKYSEKNNLEIEKIVVEVTRSSNNKHERKKIEGINKYRKEKYEELKKVYD LPNENTTLLKKLWLLRQQQGYDAYSLRKIEANDVINKPWNYDIDHIVPRSISFDDSFSNLVIVN KLDNAKKSNDLSAKQFIEKIYGIEKLKEAKENWGNWYLRNANGKAFNDKGKFIKLYTIDNLDEF DNSDFINRNLSDTSYITNALVNHLTFSNSKYKYSVVSVNGKQTSNLRNQIAFVGIKNNKETERE WKRPEGFKSINSNDFLIREEGKNDVKDDVLIKDRSFNGHHAEDAYFITIISQYFRSFKRIERLN VNYRKETRELDDLEKNNIKFKEKASFDNFLLINALDELNEKLNQMRFSRMVITKKNTQLFNETL YSGKYDKGKNTIKKVEKLNLLDNRTDKIKKIEEFFDEDKLKENELTKLHIFNHDKNLYETLKII WNEVKIEIKNKNLNEKNYFKYFVNKKLQEGKISFNEWVPILDNDFKIIRKIRYIKFSSEEKETD EIIFSQSNFLKIDQRQNFSFHNTLYWVQIWVYKNQKDQYCFISIDARNSKFEKDEIKINYEKLK TQKEKLQIINEEPILKINKGDLFENEEKELFYIVGRDEKPQKLEIKYILGKKIKDQKQIQKPVK KYFPNWKKVNLTYMGEIFKK SEQ ID NO: 353 MDNKNYRIGIDVGLNSIGFCAVEVDQHDTPLGFLNLSVYRHDAGIDPNGKKTNTTRLAMSGVAR RTRRLFRKRKRRLAALDRFIEAQGWTLPDHADYKDPYTPWLVRAELAQTPIRDENDLHEKLAIA VRHIARHRGWRSPWVPVRSLHVEQPPSDQYLALKERVEAKTLLQMPEGATPAEMVVALDLSVDV NLRPKNREKTDTRPENKKPGFLGGKLMQSDNANELRKIAKIQGLDDALLRELIELVFAADSPKG ASGELVGYDVLPGQHGKRRAEKAHPAFQRYRIASIVSNLRIRHLGSGADERLDVETQKRVFEYL LNAKPTADITWSDVAEEIGVERNLLMGTATQTADGERASAKPPVDVTNVAFATCKIKPLKEWWL NADYEARCVMVSALSHAEKLTEGTAAEVEVAEFLQNLSDEDNEKLDSFSLPIGRAAYSVDSLER LTKRMIENGEDLFEARVNEFGVSEDWRPPAEPIGARVGNPAVDRVLKAVNRYLMAAEAEWGAPL SVNIEHVREGFISKRQAVEIDRENQKRYQRNQAVRSQIADHINATSGVRGSDVTRYLAIQRQNG ECLYCGTAITFVNSEMDHIVPRAGLGSTNTRDNLVATCERCNKSKSNKPFAVWAAECGIPGVSV AEALKRVDFWIADGFASSKEHRELQKGVKDRLKRKVSDPEIDNRSMESVAWMARELAHRVQYYF DEKHTGTKVRVFRGSLTSAARKASGFESRVNFIGGNGKTRLDRRHHAMDAATVAMLRNSVAKTL VLRGNIRASERAIGAAETWKSFRGENVADRQIEESWSENMRVLVEKFNLALYNDEVSIESSLRL QLGNGKAHDDTITKLQMHKVGDAWSLTEIDRASTPALWCALTRQPDFTWKDGLPANEDRTIIVN GTHYGPLDKVGIFGKAAASLLVRGGSVDIGSAIHHARIYRIAGKKPTYGMVRVFAPDLLRYRNE DLFNVELPPQSVSMRYAEPKVREAIREGKAEYLGWLVVGDELLLDLSSETSGQIAELQQDFPGT THWTVAGFFSPSRLRLRPVYLAQEGLGEDVSEGSKSIIAGQGWRPAVNKVFGSAMPEVIRRDGL GRKRRFSYSGLPVSWQG SEQ ID NO: 354 MRLGLDIGTSSIGWWLYETDGAGSDARITGVVDGGVRIFSDGRDPKSGASLAVDRRAARAMRRR RDRYLRRRATLMKVLAETGLMPADPAEAKALEALDPFALRAAGLDEPLPLPHLGRALFHLNQRR GFKSNRKTDRGDNESGKIKDATARLDMEMMANGARTYGEFLHKRRQKATDPRHVPSVRTRLSIA NRGGPDGKEEAGYDFYPDRRHLEEEFHKLWAAQGAHHPELTETLRDLLFEKIFFQRPLKEPEVG LCLFSGHHGVPPKDPRLPKAHPLTQRRVLYETVNQLRVTADGREARPLTREERDQVIHALDNKK PTKSLSSMVLKLPALAKVLKLRDGERFTLETGVRDAIACDPLRASPAHPDRFGPRWSILDADAQ WEVISRIRRVQSDAEHAALVDWLTEAHGLDRAHAEATAHAPLPDGYGRLGLTATTRILYQLTAD VVTYADAVKACGWHHSDGRTGECFDRLPYYGEVLERHVIPGSYHPDDDDITRFGRITNPTVHIG LNQLRRLVNRIIETHGKPHQIVVELARDLKKSEEQKRADIKRIRDTTEAAKKRSEKLEELEIED NGRNRMLLRLWEDLNPDDAMRRFCPYTGTRISAAMIFDGSCDVDHILPYSRTLDDSFPNRTLCL REANRQKRNQTPWQAWGDTPHWHAIAANLKNLPENKRWRFAPDAMTRFEGENGFLDRALKDTQY LARISRSYLDTLFTKGGHVWVVPGRFTEMLRRHWGLNSLLSDAGRGAVKAKNRTDHRHHAIDAA VIAATDPGLLNRISRAAGQGEAAGQSAELIARDTPPPWEGFRDDLRVRLDRIIVSHRADHGRID HAARKQGRDSTAGQLHQETAYSIVDDIHVASRTDLLSLKPAQLLDEPGRSGQVRDPQLRKALRV ATGGKTGKDFENALRYFASKPGPYQAIRRVRIIKPLQAQARVPVPAQDPIKAYQGGSNHLFEIW RLPDGEIEAQVITSFEAHTLEGEKRPHPAAKRLLRVHKGDMVALERDGRRVVGHVQKMDIANGL FIVPHNEANADTRNNDKSDPFKWIQIGARPAIASGIRRVSVDEIGRLRDGGTRPI SEQ ID NO: 355 MLHCIAVIRVPPSEEPGFFETHADSCALCHHGCMTYAANDKAIRYRVGIDVGLRSIGFCAVEVD DEDHPIRILNSVVHVHDAGTGGPGETESLRKRSGVAARARRRGRAEKQRLKKLDVLLEELGWGV SSNELLDSHAPWHIRKRLVSEYIEDETERRQCLSVAMAHIARHRGWRNSFSKVDTLLLEQAPSD RMQGLKERVEDRTGLQFSEEVTQGELVATLLEHDGDVTIRGFVRKGGKATKVHGVLEGKYMQSD LVAELRQICRTQRVSETTFEKLVLSIFHSKEPAPSAARQRERVGLDELQLALDPAAKQPRAERA HPAFQKFKVVATLANMRIREQSAGERSLTSEELNRVARYLLNHTESESPTWDDVARKLEVPRHR LRGSSRASLETGGGLTYPPVDDTTVRVMSAEVDWLADWWDCANDESRGHMIDAISNGCGSEPDD VEDEEVNELISSATAEDMLKLELLAKKLPSGRVAYSLKTLREVTAAILETGDDLSQAITRLYGV DPGWVPTPAPIEAPVGNPSVDRVLKQVARWLKFASKRWGVPQTVNIEHTREGLKSASLLEEERE RWERFEARREIRQKEMYKRLGISGPFRRSDQVRYEILDLQDCACLYCGNEINFQTFEVDHIIPR VDASSDSRRTNLAAVCHSCNSAKGGLAFGQWVKRGDCPSGVSLENAIKRVRSWSKDRLGLTEKA MGKRKSEVISRLKTEMPYEEFDGRSMESVAWMAIELKKRIEGYFNSDRPEGCAAVQVNAYSGRL TACARRAAHVDKRVRLIRLKGDDGHHKNRFDRRNHAMDALVIALMTPAIARTIAVREDRREAQQ LTRAFESWKNFLGSEERMQDRWESWIGDVEYACDRLNELIDADKIPVTENLRLRNSGKLHADQP ESLKKARRGSKRPRPQRYVLGDALPADVINRVTDPGLWTALVRAPGFDSQLGLPADLNRGLKLR GKRISADFPIDYFPTDSPALAVQGGYVGLEFHHARLYRIIGPKEKVKYALLRVCAIDLCGIDCD DLFEVELKPSSISMRTADAKLKEAMGNGSAKQIGWLVLGDEIQIDPTKFPKQSIGKELKECGPV SSWRVSALDTPSKITLKPRLLSNEPLLKTSRVGGHESDLVVAECVEKIMKKTGWWEINALCQS GLIRVIRRNALGEVRTSPKSGLPISLNLR SEQ ID NO: 356 MRYRVGLDLGTASVGAAVFSMDEQGNPMELIWHYERLFSEPLVPDMGQLKPKKAARRLARQQRR QIDRRASRLRRIAIVSRRLGIAPGRNDSGVHGNDVPTLRAMAVNERIELGQLRAVLLRMGKKRG YGGTFKAVRKVGEAGEVASGASRLEEEMVALASVQNKDSVTVGEYLAARVEHGLPSKLKVAANN EYYAPEYALFRQYLGLPAIKGRPDCLPNMYALRHQIEHEFERIWATQSQFHDVMKDHGVKEEIR NAIFFQRPLKSPADKVGRCSLQTNLPRAPRAQIAAQNFRIEKQMADLRWGMGRRAEMLNDHQKA VIRELLNQQKELSFRKIYKELERAGCPGPEGKGLNMDRAALGGRDDLSGNTTLAAWRKLGLEDR WQELDEVTQIQVINFLADLGSPEQLDTDDWSCRFMGKNGRPRNFSDEFVAFMNELRMTDGFDRL SKMGFEGGRSSYSIKALKALTEWMIAPHWRETPETHRVDEEAAIRECYPESLATPAQGGRQSKL EPPPLTGNEVVDVALRQVRHTINMMIDDLGSVPAQIVVEMAREMKGGVTRRNDIEKQNKRFASE RKKAAQSIEENGKTPTPARILRYQLWIEQGHQCPYCESNISLEQALSGAYTNFEHILPRTLTQI GRKRSELVLAHRECNDEKGNRTPYQAFGHDDRRWRIVEQRANALPKKSSRKTRLLLLKDFEGEA LTDESIDEFADRQLHESSWLAKVTTQWLSSLGSDVYVSRGSLTAELRRRWGLDTVIPQVRFESG MPVVDEEGAEITPEEFEKFRLQWEGHRVTREMRTDRRPDKRIDHRHHLVDAIVTALTSRSLYQQ YAKAWKVADEKQRHGRVDVKVELPMPILTIRDIALEAVRSVRISHKPDRYPDGRFFEATAYGIA QRLDERSGEKVDWLVSRKSLTDLAPEKKSIDVDKVRANISRIVGEAIRLHISNIFEKRVSKGMT PQQALREPIEFQGNILRKVRCFYSKADDCVRIEHSSRRGHHYKMLLNDGFAYMEVPCKEGILYG VPNLVRPSEAVGIKRAPESGDFIRFYKGDTVKNIKTGRVYTIKQILGDGGGKLILTPVTETKPA DLLSAKWGRLKVGGRNIHLLRLCAE SEQ ID NO: 357 MIGEHVRGGCLFDDHWTPNWGAFRLPNTVRTFTKAENPKDGSSLAEPRRQARGLRRRLRRKTQR LEDLRRLLAKEGVLSLSDLETLFRETPAKDPYQLRAEGLDRPLSFPEWVRVLYHITKHRGFQSN RRNPVEDGQERSRQEEEGKLLSGVGENERLLREGGYRTAGEMLARDPKFQDHRRNRAGDYSHTL SRSLLLEEARRLFQSQRTLGNPHASSNLEEAFLHLVAFQNPFASGEDIRNKAGHCSLEPDQIRA PRRSASAETFMLLQKTGNLRLIHRRTGEERPLTDKEREQIHLLAWKQEKVTHKTLRRHLEIPEE WLFTGLPYHRSGDKAEEKLFVHLAGIHEIRKALDKGPDPAVWDTLRSRRDLLDSIADTLTFYKN EDEILPRLESLGLSPENARALAPLSFSGTAHLSLSALGKLLPHLEEGKSYTQARADAGYAAPPP DRHPKLPPLEEADWRNPVVFRALTQTRKVVNALVRRYGPPWCIHLETARELSQPAKVRRRIETE QQANEKKKQQAEREFLDIVGTAPGPGDLLKMRLWREQGGFCPYCEEYLNPTRLAEPGYAEMDHI LPYSRSLDNGWHNRVLVHGKDNRDKGNRTPFEAFGGDTARWDRLVAWVQASHLSAPKKRNLLRE DFGEEAERELKDRNLTDTRFITKTAATLLRDRLTFHPEAPKDPVMTLNGRLTAFLRKQWGLHKN RKNGDLHHALDAAVLAVASRSFVYRLSSHNAAWGELPRGREAENGFSLPYPAFRSEVLARLCPT REEILLRLDQGGVGYDEAFRNGLRPVFVSRAPSRRLRGKAHMETLRSPKWKDHPEGPRTASRIP LKDLNLEKLERMVGKDRDRKLYEALRERLAAFGGNGKKAFVAPFRKPCRSGEGPLVRSLRIFDS GYSGVELRDGGEVYAVADHESMVRVDVYAKKNRFYLVPVYVADVARGIVKNRAIVAHKSEEEWD LVDGSFDFRFSLFPGDLVEIEKKDGAYLGYYKSCHRGDGRLLLDRHDRMPRESDCGTFYVSTRK DVLSMSKYQVDPLGEIRLVGSEKPPFVL SEQ ID NO: 358 MEKKRKVTLGFDLGIASVGWAIVDSETNQVYKLGSRLFDAPDTNLERRTQRGTRRLLRRRKYRN QKFYNLVKRTEVFGLSSREAIENRFRELSIKYPNIIELKTKALSQEVCPDEIAWILHDYLKNRG YFYDEKETKEDFDQQTVESMPSYKLNEFYKKYGYFKGALSQPTESEMKDNKDLKEAFFFDFSNK EWLKEINYFFNVQKNILSETFIEEFKKIFSFTRDISKGPGSDNMPSPYGIFGEFGDNGQGGRYE HIWDKNIGKCSIFTNEQRAPKYLPSALIFNFLNELANIRLYSTDKKNIQPLWKLSSVDKLNILL NLFNLPISEKKKKLTSTNINDIVKKESIKSIMISVEDIDMIKDEWAGKEPNVYGVGLSGLNIEE SAKENKFKFQDLKILNVLINLLDNVGIKFEFKDRNDIIKNLELLDNLYLFLIYQKESNNKDSSI DLEIAKNESLNIENLKLKLKEFLLGAGNEFENHNSKTHSLSKKAIDEILPKLLDNNEGWNLEAI KNYDEEIKSQIEDNSSLMAKQDKKYLNDNFLKDAILPPNVKVTFQQAILIFNKIIQKFSKDFEI DKVVIELAREMTQDQENDALKGIAKAQKSKKSLVEERLEANNIDKSVFNDKYEKLIYKIFLWIS QDFKDPYTGAQISVNEIVNNKVEIDHIIPYSLCFDDSSANKVLVHKQSNQEKSNSLPYEYIKQG HSGWNWDEFTKYVKRVFVNNVDSILSKKERLKKSENLLTASYDGYDKLGFLARNLNDTRYATIL FRDQLNNYAEHHLIDNKKMFKVIAMNGAVTSFIRKNMSYDNKLRLKDRSDFSHHAYDAAIIALF SNKTKTLYNLIDPSLNGIISKRSEGYWVIEDRYTGEIKELKKEDWTSIKNNVQARKIAKEIEEY LIDLDDEVFFSRKTKRKTNRQLYNETIYGIATKTDEDGITNYYKKEKFSILDDKDIYLRLLRER EKFVINQSNPEVIDQIIEIIESYGKENNIPSRDEAINIKYTKNKINYNLYLKQYMRSLTKSLDQ FSEEFINQMIANKTFVLYNPTKNTTRKIKFLRLVNDVKINDIRKNQVINKFNGKNNEPKAFYEN INSLGAIVFKNSANNFKTLSINTQIAIFGDKNWDIEDFKTYNMEKIEKYKEIYGIDKTYNFHSF IFPGTILLDKQNKEFYYISSIQTVRDIIEIKFLNKIEFKDENKNQDTSKTPKRLMFGIKSIMNN YEQVDISPFGINKKIFE SEQ ID NO: 359 MGYRIGLDVGITSTGYAVLKTDKNGLPYKILTLDSVIYPRAENPQTGASLAEPRRIKRGLRRRT RRTKFRKQRTQQLFIHSGLLSKPEIEQILATPQAKYSVYELRVAGLDRRLTNSELFRVLYFFIG HRGFKSNRKAELNPENEADKKQMGQLLNSIEEIRKAIAEKGYRTVGELYLKDPKYNDHKRNKGY IDGYLSTPNRQMLVDEIKQILDKQRELGNEKLTDEFYATYLLGDENRAGIFQAQRDFDEGPGAG PYAGDQIKKMVGKDIFEPTEDRAAKATYTFQYFNLLQKMTSLNYQNTTGDTWHTLNGLDRQAII DAVFAKAEKPTKTYKPTDFGELRKLLKLPDDARFNLVNYGSLQTQKEIETVEKKTRFVDFKAYH DLVKVLPEEMWQSRQLLDHIGTALTLYSSDKRRRRYFAEELNLPAELIEKLLPLNFSKFGHLSI KSMQNIIPYLEMGQVYSEATTNTGYDFRKKQISKDTIREEITNPVVRRAVTKTIKIVEQIIRRY GKPDGINIELARELGRNFKERGDIQKRQDKNRQTNDKIAAELTELGIPVNGQNIIRYKLHKEQN GVDPYTGDQIPFERAFSEGYEVDHIIPYSISWDDSYTNKVLTSAKCNREKGNRIPMVYLANNEQ RLNALTNIADNIIRNSRKRQKLLKQKLSDEELKDWKQRNINDTRFITRVLYNYFRQAIEFNPEL EKKQRVLPLNGEVTSKIRSRWGFLKVREDGDLHHAIDATVIAAITPKFIQQVTKYSQHQEVKNN QALWHDAEIKDAEYAAEAQRMDADLFNKIFNGFPLPWPEFLDELLARISDNPVEMMKSRSWNTY TPIEIAKLKPVFVVRLANHKISGPAHLDTIRSAKLFDEKGIVLSRVSITKLKINKKGQVATGDG IYDPENSNNGDKVVYSAIRQALEAHNGSGELAFPDGYLEYVDHGTKKLVRKVRVAKKVSLPVRL KNKAAADNGSMVRIDVFNTGKKFVFVPIYIKDTVEQVLPNKAIARGKSLWYQITESDQFCFSLY PGDMVHIESKTGIKPKYSNKENNTSVVPIKNFYGYFDGADIATASILVRAHDSSYTARSIGIAG LLKFEKYQVDYFGRYHKVHEKKRQLFVKRDE SEQ ID NO: 360 MQKNINTKQNHIYIKQAQKIKEKLGDKPYRIGLDLGVGSIGFAIVSMEENDGNVLLPKEIIMVG SRIFKASAGAADRKLSRGQRNNHRHTRERMRYLWKVLAEQKLALPVPADLDRKENSSEGETSAK RFLGDVLQKDIYELRVKSLDERLSLQELGYVLYHIAGHRGSSAIRTFENDSEEAQKENTENKKI AGNIKRLMAKKNYRTYGEYLYKEFFENKEKHKREKISNAANNHKFSPTRDLVIKEAEAILKKQA GKDGFHKELTEEYIEKLTKAIGYESEKLIPESGFCPYLKDEKRLPASHKLNEERRLWETLNNAR YSDPIVDIVTGEITGYYEKQFTKEQKQKLFDYLLTGSELTPAQTKKLLGLKNTNFEDIILQGRD KKAQKIKGYKLIKLESMPFWARLSEAQQDSFLYDWNSCPDEKLLTEKLSNEYHLTEEEIDNAFN EIVLSSSYAPLGKSAMLIILEKIKNDLSYTEAVEEALKEGKLTKEKQAIKDRLPYYGAVLQEST QKIIAKGFSPQFKDKGYKTPHTNKYELEYGRIANPVVHQTLNELRKLVNEIIDILGKKPCEIGL ETARELKKSAEDRSKLSREQNDNESNRNRIYEIYIRPQQQVIITRRENPRNYILKFELLEEQKS QCPFCGGQISPNDIINNQADIEHLFPIAESEDNGRNNLVISHSACNADKAKRSPWAAFASAAKD SKYDYNRILSNVKENIPHKAWRFNQGAFEKFIENKPMAARFKTDNSYISKVAHKYLACLFEKPN IICVKGSLTAQLRMAWGLQGLMIPFAKQLITEKESESFNKDVNSNKKIRLDNRHHALDAIVIAY ASRGYGNLLNKMAGKDYKINYSERNWLSKILLPPNNIVWENIDADLESFESSVKTALKNAFISV KHDHSDNGELVKGTMYKIFYSERGYTLTTYKKLSALKLTDPQKKKTPKDFLETALLKFKGRESE MKNEKIKSAIENNKRLFDVIQDNLEKAKKLLEEENEKSKAEGKKEKNINDASIYQKAISLSGDK YVQLSKKEPGKFFAISKPTPTTTGYGYDTGDSLCVDLYYDNKGKLCGEIIRKIDAQQKNPLKYK EQGFTLFERIYGGDILEVDFDIHSDKNSFRNNTGSAPENRVFIKVGTFTEITNNNIQIWFGNII KSTGGQDDSFTINSMQQYNPRKLILSSCGFIKYRSPILKNKEG SEQ ID NO: 361 MAAFKPNPINYILGLDIGIASVGWAMVEIDEDENPICLIDLGVRVFERAEVPKTGDSLAMARRL ARSVRRLTRRRAHRLLRARRLLKREGVLQAADFDENGLIKSLPNTPWQLRAAALDRKLTPLEWS AVLLHLIKHRGYLSQRKNEGETADKELGALLKGVADNAHALQTGDFRTPAELALNKFEKESGHI RNQRGDYSHTFSRKDLQAELILLFEKQKEFGNPHVSGGLKEGIETLLMTQRPALSGDAVQKMLG HCTFEPAEPKAAKNTYTAERFIWLTKLNNLRILEQGSERPLTDTERATLMDEPYRKSKLTYAQA RKLLGLEDTAFFKGLRYGKDNAEASTLMEMKAYHAISRALEKEGLKDKKSPLNLSPELQDEIGT AFSLFKTDEDITGRLKDRIQPEILEALLKHISFDKFVQISLKALRRIVPLMEQGKRYDEACAEI YGDHYGKKNTEEKIYLPPIPADEIRNPVVLRALSQARKVINGVVRRYGSPARIHIETAREVGKS FKDRKEIEKRQEENRKDREKAAAKFREYFPNFVGEPKSKDILKLRLYEQQHGKCLYSGKEINLG RLNEKGYVEIDHALPFSRTWDDSFNNKVLVLGSENQNKGNQTPYEYFNGKDNSREWQEFKARVE TSRFPRSKKQRILLQKFDEDGFKERNLNDTRYVNRFLCQFVADRMRLTGKGKKRVFASNGQITN LLRGFWGLRKVRAENDRHHALDAVVVACSTVAMQQKITRFVRYKEMNAFDGKTIDKETGEVLHQ KTHFPQPWEFFAQEVMIRVFGKPDGKPEFEEADTPEKLRTLLAEKLSSRPEAVHEYVTPLFVSR APNRKMSGQGHMETVKSAKRLDEGVSVLRVPLTQLKLKDLEKMVNREREPKLYEALKARLEAHK DDPAKAFAEPFYKYDKAGNRTQQVKAVRVEQVQKTGVWVRNHNGIADNATMVRVDVFEKGDKYY LVPIYSWQVAKGILPDRAVVQGKDEEDWQLIDDSFNFKFSLHPNDLVEVITKKARMFGYFASCH RGTGNINIRIHDLDHKIGKNGILEGIGVKTALSFQKYQIDELGKEIRPCRLKKRPPVR SEQ ID NO: 362 MQTTNLSYILGLDLGIASVGWAVVEINENEDPIGLIDVGVRIFERAEVPKTGESLALSRRLARS TRRLIRRRAHRLLLAKRFLKREGILSTIDLEKGLPNQAWELRVAGLERRLSAIEWGAVLLHLIK HRGYLSKRKNESQTNNKELGALLSGVAQNHQLLQSDDYRTPAELALKKFAKEEGHIRNQRGAYT HTFNRLDLLAELNLLFAQQHQFGNPHCKEHIQQYMTELLMWQKPALSGEAILKMLGKCTHEKNE FKAAKHTYSAERFVWLTKLNNLRILEDGAERALNEEERQLLINHPYEKSKLTYAQVRKLLGLSE QAIFKHLRYSKENAESATFMELKAWHAIRKALENQGLKDTWQDLAKKPDLLDEIGTAFSLYKTD EDIQQYLTNKVPNSVINALLVSLNFDKFIELSLKSLRKILPLMEQGKRYDQACREIYGHHYGEA NQKTSQLLPAIPAQEIRNPVVLRTLSQARKVINAIIRQYGSPARVHIETGRELGKSFKERREIQ KQQEDNRTKRESAVQKFKELFSDFSSEPKSKDILKFRLYEQQHGKCLYSGKEINIHRLNEKGYV EIDHALPFSRTWDDSFNNKVLVLASENQNKGNQTPYEWLQGKINSERWKNFVALVLGSQCSAAK KQRLLTQVIDDNKFIDRNLNDTRYIARFLSNYIQENLLLVGKNKKNVFTPNGQITALLRSRWGL IKARENNNRHHALDAIVVACATPSMQQKITRFIRFKEVHPYKIENRYEMVDQESGEIISPHFPE PWAYFRQEVNIRVFDNHPDTVLKEMLPDRPQANHQFVQPLFVSRAPTRKMSGQGHMETIKSAKR LAEGISVLRIPLTQLKPNLLENMVNKEREPALYAGLKARLAEFNQDPAKAFATPFYKQGGQQVK AIRVEQVQKSGVLVRENNGVADNASIVRTDVFIKNNKFFLVPIYTWQVAKGILPNKAIVAHKNE DEWEEMDEGAKFKFSLFPNDLVELKTKKEYFFGYYIGLDRATGNISLKEHDGEISKGKDGVYRV GVKLALSFEKYQVDELGKNRQICRPQQRQPVR SEQ ID NO: 363 MGIRFAFDLGTNSIGWAVWRTGPGVFGEDTAASLDGSGVLIFKDGRNPKDGQSLATMRRVPRQS RKRRDRFVLRRRDLLAALRKAGLFPVDVEEGRRLAATDPYHLRAKALDESLTPHEMGRVIFHLN QRRGFRSNRKADRQDREKGKIAEGSKRLAETLAATNCRTLGEFLWSRHRGTPRTRSPTRIRMEG EGAKALYAFYPTREMVRAEFERLWTAQSRFAPDLLTPERHEEIAGILFRQRDLAPPKIGCCTFE PSERRLPRALPSVEARGIYERLAHLRITTGPVSDRGLTRPERDVLASALLAGKSLTFKAVRKTL KILPHALVNFEEAGEKGLDGALTAKLLSKPDHYGAAWHGLSFAEKDTFVGKLLDEADEERLIRR LVTENRLSEDAARRCASIPLADGYGRLGRTANTEILAALVEETDETGTVVTYAEAVRRAGERTG RNWHHSDERDGVILDRLPYYGEILQRHVVPGSGEPEEKNEAARWGRLANPTVHIGLNQLRKVVN RLIAAHGRPDQIVVELARELKLNREQKERLDRENRKNREENERRTAILAEHGQRDTAENKIRLR LFEEQARANAGIALCPYTGRAIGIAELFTSEVEIDHILPVSLTLDDSLANRVLCRREANREKRR QTPFQAFGATPAWNDIVARAAKLPPNKRWRFDPAALERFEREGGFLGRQLNETKYLSRLAKIYL GKICDPDRVYVTPGTLTGLLRARWGLNSILSDSNFKNRSDHRHHAVDAVVIGVLTRGMIQRIAH DAARAEDQDLDRVFRDVPVPFEDFRDHVRERVSTITVAVKPEHGKGGALHEDTSYGLVPDTDPN AALGNLVVRKPIRSLTAGEVDRVRDRALRARLGALAAPFRDESGRVRDAKGLAQALEAFGAENG IRRVRILKPDASVVTIADRRTGVPYRAVAPGENHHVDIVQMRDGSWRGFAASVFEVNRPGWRPE WEVKKLGGKLVMRLHKGDMVELSDKDGQRRVKVVQQIEISANRVRLSPHNDGGKLQDRHADADD PFRWDLATIPLLKDRGCVAVRVDPIGWTLRRSNV SEQ ID NO: 364 MMEVFMGRLVLGLDIGITSVGFGIIDLDESEIVDYGVRLFKEGTAAENETRRTKRGGRRLKRRR VTRREDMLHLLKQAGIISTSFHPLNNPYDVRVKGLNERLNGEELATALLHLCKHRGSSVETIED DEAKAKEAGETKKVLSMNDQLLKSGKYVCEIQKERLRTNGHIRGHENNFKTRAYVDEAFQILSH QDLSNELKSAIITIISRKRMYYDGPGGPLSPTPYGRYTYFGQKEPIDLIEKMRGKCSLFPNEPR APKLAYSAELFNLLNDLNNLSIEGEKLTSEQKAMILKIVHEKGKITPKQLAKEVGVSLEQIRGF RIDTKGSPLLSELTGYKMIREVLEKSNDEHLEDHVFYDEIAEILTKTKDIEGRKKQISELSSDL NEESVHQLAGLTKFTAYHSLSFKALRLINEEMLKTELNQMQSITLFGLKQNNELSVKGMKNIQA DDTAILSPVAKRAQRETFKVVNRLREIYGEEDSIVVEMAREKNSEEQRKAIRERQKFFEMRNKQ VADIIGDDRKINAKLREKLVLYQEQDGKTAYSLEPIDLKLLIDDPNAYEVDHIIPISISLDDSI TNKVLVTHRENQEKGNLTPISAFVKGRFTKGSLAQYKAYCLKLKEKNIKTNKGYRKKVEQYLLN ENDIYKYDIQKEFINRNLVDTSYASRVVLNTLTTYFKQNEIPTKVFTVKGSLTNAFRRKINLKK DRDEDYGHHAIDALIIASMPKMRLLSTIFSRYKIEDIYDESTGEVFSSGDDSMYYDDRYFAFIA SLKAIKVRKFSHKIDTKPNRSVADETIYSTRVIDGKEKVVKKYKDIYDPKFTALAEDILNNAYQ EKYLMALHDPQTFDQIVKVVNYYFEEMSKSEKYFTKDKKGRIKISGMNPLSLYRDEHGMLKKYS KKGDGPAITQMKYFDGVLGNHIDISAHYQVRDKKVVLQQISPYRTDFYYSKENGYKFVTIRYKD VRWSEKKKKYVIDQQDYAMKKAEKKIDDTYEFQFSMHRDELIGITKAEGEALIYPDETWHNFNF FFHAGETPEILKFTATNNDKSNKIEVKPIHCYCKMRLMPTISKKIVRIDKYATDVVGNLYKVKK NTLKFEFD SEQ ID NO: 365 MKKILGVDLGITSFGYAILQETGKDLYRCLDNSVVMRNNPYDEKSGESSQSIRSTQKSMRRLIE KRKKRIRCVAQTMERYGILDYSETMKINDPKNNPIKNRWQLRAVDAWKRPLSPQELFAIFAHMA KHRGYKSIATEDLIYELELELGLNDPEKESEKKADERRQVYNALRHLEELRKKYGGETIAQTIH RAVEAGDLRSYRNHDDYEKMIRREDIEEEIEKVLLRQAELGALGLPEEQVSELIDELKACITDQ EMPTIDESLFGKCTFYKDELAAPAYSYLYDLYRLYKKLADLNIDGYEVTQEDREKVIEWVEKKI AQGKNLKKITHKDLRKILGLAPEQKIFGVEDERIVKGKKEPRTFVPFFFLADIAKFKELFASIQ KHPDALQIFRELAEILQRSKTPQEALDRLRALMAGKGIDTDDRELLELFKNKRSGTRELSHRYI LEALPLFLEGYDEKEVQRILGFDDREDYSRYPKSLRHLHLREGNLFEKEENPINNHAVKSLASW ALGLIADLSWRYGPFDEIILETTRDALPEKIRKEIDKAMREREKALDKIIGKYKKEFPSIDKRL ARKIQLWERQKGLDLYSGKVINLSQLLDGSADIEHIVPQSLGGLSTDYNTIVTLKSVNAAKGNR LPGDWLAGNPDYRERIGMLSEKGLIDWKKRKNLLAQSLDEIYTENTHSKGIRATSYLEALVAQV LKRYYPFPDPELRKNGIGVRMIPGKVTSKTRSLLGIKSKSRETNFHHAEDALILSTLTRGWQNR LHRMLRDNYGKSEAELKELWKKYMPHIEGLTLADYIDEAFRRFMSKGEESLFYRDMFDTIRSIS YWVDKKPLSASSHKETVYSSRHEVPTLRKNILEAFDSLNVIKDRHKLTTEEFMKRYDKEIRQKL WLHRIGNTNDESYRAVEERATQIAQILTRYQLMDAQNDKEIDEKFQQALKELITSPIEVTGKLL RKMRFVYDKLNAMQIDRGLVETDKNMLGIHISKGPNEKLIFRRMDVNNAHELQKERSGILCYLN EMLFIFNKKGLIHYGCLRSYLEKGQGSKYIALFNPRFPANPKAQPSKFTSDSKIKQVGIGSATG IIKAHLDLDGHVRSYEVFGTLPEGSIEWFKEESGYGRVEDDPHH SEQ ID NO: 366 MRPIEPWILGLDIGTDSLGWAVFSCEEKGPPTAKELLGGGVRLFDSGRDAKDHTSRQAERGAFR RARRQTRTWPWRRDRLIALFQAAGLTPPAAETRQIALALRREAVSRPLAPDALWAALLHLAHHR GFRSNRIDKRERAAAKALAKAKPAKATAKATAPAKEADDEAGEWEGAEAALRQRMAASGAPTVG ALLADDLDRGQPVRMRYNQSDRDGVVAPTRALIAEELAEIVARQSSAYPGLDWPAVTRLVLDQR PLRSKGAGPCAFLPGEDRALRALPTVQDFIIRQTLANLRLPSTSADEPRPLTDEEHAKALALLS TARFVEWPALRRALGLKRGVKFTAETERNGAKQAARGTAGNLTEAILAPLIPGWSGWDLDRKDR VFSDLWAARQDRSALLALIGDPRGPTRVTEDETAEAVADAIQIVLPTGRASLSAKAARAIAQAM APGIGYDEAVTLALGLHHSHRPRQERLARLPYYAAALPDVGLDGDPVGPPPAEDDGAAAEAYYG RIGNISVHIALNETRKIVNALLHRHGPILRLVMVETTRELKAGADERKRMIAEQAERERENAEI DVELRKSDRWMANARERRQRVRLARRQNNLCPYTSTPIGHADLLGDAYDIDHVIPLARGGRDSL DNMVLCQSDANKTKGDKTPWEAFHDKPGWIAQRDDFLARLDPQTAKALAWRFADDAGERVARKS AEDEDQGFLPRQLTDTGYIARVALRYLSLVTNEPNAVVATNGRLTGLLRLAWDITPGPAPRDLL PTPRDALRDDTAARRFLDGLTPPPLAKAVEGAVQARLAALGRSRVADAGLADALGLTLASLGGG GKNRADHRHHFIDAAMIAVTTRGLINQINQASGAGRILDLRKWPRTNFEPPYPTFRAEVMKQWD HIHPSIRPAHRDGGSLHAATVFGVRNRPDARVLVQRKPVEKLFLDANAKPLPADKIAEIIDGFA SPRMAKRFKALLARYQAAHPEVPPALAALAVARDPAFGPRGMTANTVIAGRSDGDGEDAGLITP FRANPKAAVRTMGNAVYEVWEIQVKGRPRWTHRVLTRFDRTQPAPPPPPENARLVMRLRRGDLV YWPLESGDRLFLVKKMAVDGRLALWPARLATGKATALYAQLSCPNINLNGDQGYCVQSAEGIRK EKIRTTSCTALGRLRLSKKAT SEQ ID NO: 367 MKYTLGLDVGIASVGWAVIDKDNNKIIDLGVRCFDKAEESKTGESLATARRIARGMRRRISRRS QRLRLVKKLFVQYEIIKDSSEFNRIFDTSRDGWKDPWELRYNALSRILKPYELVQVLTHITKRR GFKSNRKEDLSTTKEGVVITSIKNNSEMLRTKNYRTIGEMIFMETPENSNKRNKVDEYIHTIAR EDLLNEIKYIFSIQRKLGSPFVTEKLEHDFLNIWEFQRPFASGDSILSKVGKCTLLKEELRAPT SCYTSEYFGLLQSINNLVLVEDNNTLTLNNDQRAKIIEYAHFKNEIKYSEIRKLLDIEPEILFK AHNLTHKNPSGNNESKKFYEMKSYHKLKSTLPTDIWGKLHSNKESLDNLFYCLTVYKNDNEIKD YLQANNLDYLIEYIAKLPTFNKFKHLSLVAMKRIIPFMEKGYKYSDACNMAELDFTGSSKLEKC NKLTVEPIIENVTNPVVIRALTQARKVINAIIQKYGLPYMVNIELAREAGMTRQDRDNLKKEHE NNRKAREKISDLIRQNGRVASGLDILKWRLWEDQGGRCAYSGKPIPVCDLLNDSLTQIDHIYPY SRSMDDSYMNKVLVLTDENQNKRSYTPYEVWGSTEKWEDFEARIYSMHLPQSKEKRLLNRNFIT KDLDSFISRNLNDTRYISRFLKNYIESYLQFSNDSPKSCVVCVNGQCTAQLRSRWGLNKNREES DLHHALDAAVIACADRKIIKEITNYYNERENHNYKVKYPLPWHSFRQDLMETLAGVFISRAPRR KITGPAHDETIRSPKHFNKGLTSVKIPLTTVTLEKLETMVKNTKGGISDKAVYNVLKNRLIEHN NKPLKAFAEKIYKPLKNGTNGAIIRSIRVETPSYTGVFRNEGKGISDNSLMVRVDVFKKKDKYY LVPIYVAHMIKKELPSKAIVPLKPESQWELIDSTHEFLFSLYQNDYLVIKTKKGITEGYYRSCH RGTGSLSLMPHFANNKNVKIDIGVRTAISIEKYNVDILGNKSIVKGEPRRGMEKYNSFKSN SEQ ID NO: 368 MIRTLGIDIGIASIGWAVIEGEYTDKGLENKEIVASGVRVFTKAENPKNKESLALPRTLARSAR RRNARKKGRIQQVKHYLSKALGLDLECFVQGEKLATLFQTSKDFLSPWELRERALYRVLDKEEL ARVILHIAKRRGYDDITYGVEDNDSGKIKKAIAENSKRIKEEQCKTIGEMMYKLYFQKSLNVRN KKESYNRCVGRSELREELKTIFQIQQELKSPWVNEELIYKLLGNPDAQSKQEREGLIFYQRPLK GFGDKIGKCSHIKKGENSPYRACKHAPSAEEFVALTKSINFLKNLTNRHGLCFSQEDMCVYLGK ILQEAQKNEKGLTYSKLKLLLDLPSDFEFLGLDYSGKNPEKAVFLSLPSTFKLNKITQDRKTQD KIANILGANKDWEAILKELESLQLSKEQIQTIKDAKLNFSKHINLSLEALYHLLPLMREGKRYD EGVEILQERGIFSKPQPKNRQLLPPLSELAKEESYFDIPNPVLRRALSEFRKVVNALLEKYGGF HYFHIELTRDVCKAKSARMQLEKINKKNKSENDAASQLLEVLGLPNTYNNRLKCKLWKQQEEYC LYSGEKITIDHLKDQRALQIDHAFPLSRSLDDSQSNKVLCLTSSNQEKSNKTPYEWLGSDEKKW DMYVGRVYSSNFSPSKKRKLTQKNFKERNEEDFLARNLVDTGYIGRVTKEYIKHSLSFLPLPDG KKEHIRIISGSMTSTMRSFWGVQEKNRDHHLHHAQDAIIIACIEPSMIQKYTTYLKDKETHRLK SHQKAQILREGDHKLSLRWPMSNFKDKIQESIQNIIPSHHVSHKVTGELHQETVRTKEFYYQAF GGEEGVKKALKFGKIREINQGIVDNGAMVRVDIFKSKDKGKFYAVPIYTYDFAIGKLPNKAIVQ GKKNGIIKDWLEMDENYEFCFSLFKNDCIKIQTKEMQEAVLAIYKSTNSAKATIELEHLSKYAL KNEDEEKMFTDTDKEKNKTMTRESCGIQGLKVFQKVKLSVLGEVLEHKPRNRQNIALKTTPKHV SEQ ID NO: 369 MKYSIGLDIGIASVGWSVINKDKERIEDMGVRIFQKAENPKDGSSLASSRREKRGSRRRNRRKK HRLDRIKNILCESGLVKKNEIEKIYKNAYLKSPWELRAKSLEAKISNKEIAQILLHIAKRRGFK SFRKTDRNADDTGKLLSGIQENKKIMEEKGYLTIGDMVAKDPKFNTHVRNKAGSYLFSFSRKLL EDEVRKIQAKQKELGNTHFTDDVLEKYIEVFNSQRNFDEGPSKPSPYYSEIGQIAKMIGNCTFE SSEKRTAKNTWSGERFVFLQKLNNFRIVGLSGKRPLTEEERDIVEKEVYLKKEVRYEKLRKILY LKEEERFGDLNYSKDEKQDKKTEKTKFISLIGNYTIKKLNLSEKLKSEIEEDKSKLDKIIEILT FNKSDKTIESNLKKLELSREDIEILLSEEFSGTLNLSLKAIKKILPYLEKGLSYNEACEKADYD YKNNGIKFKRGELLPVVDKDLIANPVVLRAISQTRKVVNAIIRKYGTPHTIHVEVARDLAKSYD DRQTIIKENKKRELENEKTKKFISEEFGIKNVKGKLLLKYRLYQEQEGRCAYSRKELSLSEVIL DESMTDIDHIIPYSRSMDDSYSNKVLVLSGENRKKSNLLPKEYFDRQGRDWDTFVLNVKAMKIH PRKKSNLLKEKFTREDNKDWKSRALNDTRYISRFVANYLENALEYRDDSPKKRVFMIPGQLTAQ LRARWRLNKVRENGDLHHALDAAVVAVTDQKAINNISNISRYKELKNCKDVIPSIEYHADEETG EVYFEEVKDTRFPMPWSGFDLELQKRLESENPREEFYNLLSDKRYLGWFNYEEGFIEKLRPVFV SRMPNRGVKGQAHQETIRSSKKISNQIAVSKKPLNSIKLKDLEKMQGRDTDRKLYEALKNRLEE YDDKPEKAFAEPFYKPTNSGKRGPLVRGIKVEEKQNVGVYVNGGQASNGSMVRIDVFRKNGKFY TVPIYVHQTLLKELPNRAINGKPYKDWDLIDGSFEFLYSFYPNDLIEIEFGKSKSIKNDNKLTK TEIPEVNLSEVLGYYRGMDTSTGAATIDTQDGKIQMRIGIKTVKNIKKYQVDVLGNVYKVKREK RQTF SEQ ID NO: 370 MSKKVSRRYEEQAQEICQRLGSRPYSIGLDLGVGSIGVAVAAYDPIKKQPSDLVFVSSRIFIPS TGAAERRQKRGQRNSLRHRANRLKFLWKLLAERNLMLSYSEQDVPDPARLRFEDAVVRANPYEL RLKGLNEQLTLSELGYALYHIANHRGSSSVRTFLDEEKSSDDKKLEEQQAMTEQLAKEKGISTF IEVLTAFNTNGLIGYRNSESVKSKGVPVPTRDIISNEIDVLLQTQKQFYQEILSDEYCDRIVSA ILFENEKIVPEAGCCPYFPDEKKLPRCHFLNEERRLWEAINNARIKMPMQEGAAKRYQSASFSD EQRHILFHIARSGTDITPKLVQKEFPALKTSIIVLQGKEKAIQKIAGFRFRRLEEKSFWKRLSE EQKDDFFSAWTNTPDDKRLSKYLMKHLLLTENEVVDALKTVSLIGDYGPIGKTATQLLMKHLED GLTYTEALERGMETGEFQELSVWEQQSLLPYYGQILTGSTQALMGKYWHSAFKEKRDSEGFFKP NTNSDEEKYGRIANPVVHQTLNELRKLMNELITILGAKPQEITVELARELKVGAEKREDIIKQQ TKQEKEAVLAYSKYCEPNNLDKRYIERFRLLEDQAFVCPYCLEHISVADIAAGRADVDHIFPRD DTADNSYGNKVVAHRQCNDIKGKRTPYAAFSNTSAWGPIMHYLDETPGMWRKRRKFETNEEEYA KYLQSKGFVSRFESDNSYIAKAAKEYLRCLFNPNNVTAVGSLKGMETSILRKAWNLQGIDDLLG SRHWSKDADTSPTMRKNRDDNRHHGLDAIVALYCSRSLVQMINTMSEQGKRAVEIEAMIPIPGY ASEPNLSFEAQRELFRKKILEFMDLHAFVSMKTDNDANGALLKDTVYSILGADTQGEDLVFVVK KKIKDIGVKIGDYEEVASAIRGRITDKQPKWYPMEMKDKIEQLQSKNEAALQKYKESLVQAAAV LEESNRKLIESGKKPIQLSEKTISKKALELVGGYYYLISNNKRTKTFVVKEPSNEVKGFAFDTG SNLCLDFYHDAQGKLCGEIIRKIQAMNPSYKPAYMKQGYSLYVRLYQGDVCELRASDLTEAESN LAKTTHVRLPNAKPGRTFVIIITFTEMGSGYQIYFSNLAKSKKGQDTSFTLTTIKNYDVRKVQL SSAGLVRYVSPLLVDKIEKDEVALCGE SEQ ID NO: 371 MNQKFILGLDIGITSVGYGLIDYETKNIIDAGVRLFPEANVENNEGRRSKRGSRRLKRRRIHRL ERVKKLLEDYNLLDQSQIPQSTNPYAIRVKGLSEALSKDELVIALLHIAKRRGIHKIDVIDSND DVGNELSTKEQLNKNSKLLKDKFVCQIQLERMNEGQVRGEKNRFKTADIIKEIIQLLNVQKNFH QLDENFINKYIELVEMRREYFEGPGKGSPYGWEGDPKAWYETLMGHCTYFPDELRSVKYAYSAD LFNALNDLNNLVIQRDGLSKLEYHEKYHIIENVFKQKKKPTLKQIANEINVNPEDIKGYRITKS GKPQFTEFKLYHDLKSVLFDQSILENEDVLDQIAEILTIYQDKDSIKSKLTELDILLNEEDKEN IAQLTGYTGTHRLSLKCIRLVLEEQWYSSRNQMEIFTHLNIKPKKINLTAANKIPKAMIDEFIL SPVVKRTFGQAINLINKIIEKYGVPEDIIIELARENNSKDKQKFINEMQKKNENTRKRINEIIG KYGNQNAKRLVEKIRLHDEQEGKCLYSLESIPLEDLLNNPNHYEVDHIIPRSVSFDNSYHNKVL VKQSENSKKSNLTPYQYFNSGKSKLSYNQFKQHILNLSKSQDRISKKKKEYLLEERDINKFEVQ KEFINRNLVDTRYATRELTNYLKAYFSANNMNVKVKTINGSFTDYLRKVWKFKKERNHGYKHHA EDALIIANADFLFKENKKLKAVNSVLEKPEIESKQLDIQVDSEDNYSEMFIIPKQVQDIKDFRN FKYSHRVDKKPNRQLINDTLYSTRKKDNSTYIVQTIKDIYAKDNTTLKKQFDKSPEKFLMYQHD PRTFEKLEVIMKQYANEKNPLAKYHEETGEYLTKYSKKNNGPIVKSLKYIGNKLGSHLDVTHQF KSSTKKLVKLSIKPYRFDVYLTDKGYKFITISYLDVLKKDNYYYIPEQKYDKLKLGKAIDKNAK FIASFYKNDLIKLDGEIYKIIGVNSDTRNMIELDLPDIRYKEYCELNNIKGEPRIKKTIGKKVN SIEKLTTDVLGNVFTNTQYTKPQLLFKRGN SEQ ID NO: 372 MIMKLEKWRLGLDLGTNSIGWSVFSLDKDNSVQDLIDMGVRIFSDGRDPKTKEPLAVARRTARS QRKLIYRRKLRRKQVFKFLQEQGLFPKTKEECMTLKSLNPYELRIKALDEKLEPYELGRALFNL AVRRGFKSNRKDGSREEVSEKKSPDEIKTQADMQTHLEKAIKENGCRTITEFLYKNQGENGGIR FAPGRMTYYPTRKMYEEEFNLIRSKQEKYYPQVDWDDIYKAIFYQRPLKPQQRGYCIYENDKER TFKAMPCSQKLRILQDIGNLAYYEGGSKKRVELNDNQDKVLYELLNSKDKVTFDQMRKALCLAD SNSFNLEENRDFLIGNPTAVKMRSKNRFGKLWDEIPLEEQDLIIETIITADEDDAVYEVIKKYD LTQEQRDFIVKNTILQSGTSMLCKEVSEKLVKRLEEIADLKYHEAVESLGYKFADQTVEKYDLL PYYGKVLPGSTMEIDLSAPETNPEKHYGKISNPTVHVALNQTRVVVNALIKEYGKPSQIAIELS RDLKNNVEKKAEIARKQNQRAKENIAINDTISALYHTAFPGKSFYPNRNDRMKYRLWSELGLGN KCIYCGKGISGAELFTKEIEIEHILPFSRTLLDAESNLTVAHSSCNAFKAERSPFEAFGTNPSG YSWQEIIQRANQLKNTSKKNKFSPNAMDSFEKDSSFIARQLSDNQYIAKAALRYLKCLVENPSD VWTTNGSMTKLLRDKWEMDSILCRKFTEKEVALLGLKPEQIGNYKKNRFDHRHHAIDAVVIGLT DRSMVQKLATKNSHKGNRIEIPEFPILRSDLIEKVKNIVVSFKPDHGAEGKLSKETLLGKIKLH GKETFVCRENIVSLSEKNLDDIVDEIKSKVKDYVAKHKGQKIEAVLSDFSKENGIKKVRCVNRV QTPIEITSGKISRYLSPEDYFAAVIWEIPGEKKTFKAQYIRRNEVEKNSKGLNVVKPAVLENGK PHPAAKQVCLLHKDDYLEFSDKGKMYFCRIAGYAATNNKLDIRPVYAVSYCADWINSTNETMLT GYWKPTPTQNWVSVNVLFDKQKARLVTVSPIGRVFRK SEQ ID NO: 373 MSSKAIDSLEQLDLFKPQEYTLGLDLGIKSIGWAILSGERIANAGVYLFETAEELNSTGNKLIS KAAERGRKRRIRRMLDRKARRGRHIRYLLEREGLPTDELEEVVVHQSNRTLWDVRAEAVERKLT KQELAAVLFHLVRHRGYFPNTKKLPPDDESDSADEEQGKINRATSRLREELKASDCKTIGQFLA QNRDRQRNREGDYSNLMARKLVFEEALQILAFQRKQGHELSKDFEKTYLDVLMGQRSGRSPKLG NCSLIPSELRAPSSAPSTEWFKFLQNLGNLQISNAYREEWSIDAPRRAQIIDACSQRSTSSYWQ IRRDFQIPDEYRFNLVNYERRDPDVDLQEYLQQQERKTLANFRNWKQLEKIIGTGHPIQTLDEA ARLITLIKDDEKLSDQLADLLPEASDKAITQLCELDFTTAAKISLEAMYRILPHMNOGMGFFDA CQQESLPEIGVPPAGDRVPPFDEMYNPVVNRVLSQSRKLINAVIDEYGMPAKIRVELARDLGKG RELRERIKLDQLDKSKONDQRAEDFRAEFQQAPRGDQSLRYRLWKEQNCTCPYSGRMIPVNSVL SEDTQIDHILPISQSFDNSLSNKVLCFTEENAQKSNRTPFEYLDAADFQRLEAISGNWPEAKRN KLLHKSFGKVAEEWKSRALNDTRYLTSALADHLRHHLPDSKIQTVNGRITGYLRKQWGLEKDRD KHTHHAVDAIVVACTTPAIVQQVTLYHQDIRRYKKLGEKRPTPWPETFRQDVLDVEEEIFITRQ PKKVSGGIQTKDTLRKHRSKPDRQRVALTKVKLADLERLVEKDASNRNLYEHLKQCLEESGDQP TKAFKAPFYMPSGPEAKQRPILSKVTLLREKPEPPKQLTELSGGRRYDSMAQGRLDIYRYKPGG KRKDEYRVVLQRMIDLMRGEENVHVFQKGVPYDQGPEIEQNYTFLFSLYFDDLVEFQRSADSEV IRGYYRTFNIANGQLKISTYLEGRQDFDFFGANRLAHFAKVQVNLLGKVIK SEQ ID NO: 374 MRSLRYRLALDLGSTSLGWALFRLDACNRPTAVIKAGVRIFSDGRNPKDGSSLAVTRRAARAMR RRRDRLLKRKTRMQAKLVEHGFFPADAGKRKALEQLNPYALRAKGLQEALLPGEFARALFHINQ RRGFKSNRKTDKKDNDSGVLKKAIGQLRQQMAEQGSRTVGEYLWTRLQQGQGVRARYREKPYTT EEGKKRIDKSYDLYIDRAMIEQEFDALWAAQAAFNPTLFHEAARADLKDTLLHQRPLRPVKPGR CTLLPEEERAPLALPSTORFRIHQEVNHLRLLDENLREVALTLAQRDAVVTALETKAKLSFEQI RKLLKLSGSVQFNLEDAKRTELKGNATSAALARKELFGAAWSGFDEALQDEIVWQLVTEEGEGA LIAWLQTHTGVDEARAQAIVDVSLPEGYGNLSRKALARIVPALRAAVITYDKAVQAAGFDHHSQ LGFEYDASEVEDLVHPETGEIRSVFKQLPYYGKALQRHVAFGSGKPEDPDEKRYGKIANPTVHI GLNQVRMVVNALIRRYGRPTEVVIELARDLKQSREQKVEAQRRQADNQRRNARIRRSIAEVLGI GEERVRGSDIQKWICWEELSFDAADRRCPYSGVQISAAMLLSDEVEVEHILPFSKTLDDSLNNR TVAMRQANRIKRNRTPWDARAEFEAQGWSYEDILQRAERMPLRKRYRFAPDGYERWLGDDKDFL ARALNDTRYLSRVAAEYLRLVCPGTRVIPGQLTALLRGKFGLNDVLGLDGEKNRNDHRHHAVDA CVIGVTDQGLMQRFATASAQARGDGLTRLVDGMPMPWPTYRDHVERAVRHIWVSHRPDHGFEGA MMEETSYGIRKDGSIKQRRKADGSAGREISNLIRIHEATQPLRHGVSADGQPLAYKGYVGGSNY CIEITVNDKGKWEGEVISTFRAYGVVRAGGMGRLRNPHEGQNGRKLIMRLVIGDSVRLEVDGAE RTMRIVKISGSNGQIFMAPIHEANVDARNTDKQDAFTYTSKYAGSLQKAKTRRVTISPIGEVRD PGFKG SEQ ID NO: 375 MARPAFRAPRREHVNGWTPDPHRISKPFFILVSWHLLSRVVIDSSSGCFPGTSRDHTDKFAEWE CAVQPYRLSFDLGTNSIGWGLLNLDRQGKPREIRALGSRIFSDGRDPQDKASLAVARRLARQMR RRRDRYLTRRTRLMGALVRFGLMPADPAARKRLEVAVDPYLARERATRERLEPFEIGRALFHLN QRRGYKPVRTATKPDEEAGKVKEAVERLEAAIAAAGAPTLGAWFAWRKTRGETLRARLAGKGKE AAYPFYPARRMLEAEFDTLWAEQARHHPDLLTAEAREILRHRIFHQRPLKPPPVGRCTLYPDDG RAPRALPSAQRLRLFQELASLRVIHLDLSERPLTPAERDRIVAFVQGRPPKAGRKPGKVQKSVP FEKLRGLLELPPGTGFSLESDKRPELLGDETGARIAPAFGPGWTALPLEEQDALVELLLTEAEP ERAIAALTARWALDEATAAKLAGATLPDFHGRYGRRAVAELLPVLERETRGDPDGRVRPIRLDE AVKLLRGGKDHSDFSREGALLDALPYYGAVLERHVAFGTGNPADPEEKRVGRVANPTVHIALNQ LRHLVNAILARHGRPEEIVIELARDLKRSAEDRRREDKRQADNQKRNEERKRLILSLGERPTPR NLLKLRLWEEQGPVENRRCPYSGETISMRMLLSEQVDIDHILPFSVSLDDSAANKVVCLREANR IKRNRSPWEAFGHDSERWAGILARAEALPKNKRWRFAPDALEKLEGEGGLRARHLNDTRHLSRL AVEYLRCVCPKVRVSPGRLTALLRRRWGIDAILAEADGPPPEVPAETLDPSPAEKNRADHRHHA LDAVVIGCIDRSMVQRVQLAAASAEREAAAREDNIRRVLEGFKEEPWDGFRAELERRARTIVVS HRPEHGIGGALHKETAYGPVDPPEEGFNLVVRKPIDGLSKDEINSVRDPRLRRALIDRLAIRRR DANDPATALAKAAEDLAAQPASRGIRRVRVLKKESNPIRVEHGGNPSGPRSGGPFHKLLLAGEV HHVDVALRADGRRWVGHWVTLFEAHGGRGADGAAAPPRLGDGERFLMRLHKGDCLKLEHKGRVR VMQVVKLEPSSNSVVVVEPHQVKTDRSKHVKISCDQLRARGARRVTVDPLGRVRVHAPGARVGI GGDAGRTAMEPAEDIS SEQ ID NO: 376 MKRTSLRAYRLGVDLGANSLGWFVVWLDDHGQPEGLGPGGVRIFPDGRNPQSKQSNAAGRRLAR SARRRRDRYLQRRGKLMGLLVKHGLMPADEPARKRLECLDPYGLRAKALDEVLPLHHVGRALFH LNQRRGLFANRAIEQGDKDASAIKAAAGRLQTSMQACGARTLGEFLNRRHQLRATVRARSPVGG DVQARYEFYPTRAMVDAEFEAIWAAQAPHHPTMTAEAHDTIREAIFSQRAMKRPSIGKCSLDPA TSQDDVDGFRCAWSHPLAQRFRIWQDVRNLAVVETGPTSSRLGKEDQDKVARALLQTDQLSFDE IRGLLGLPSDARFNLESDRRDHLKGDATGAILSARRHFGPAWHDRSLDRQIDIVALLESALDEA AIIASLGTTHSLDEAAAQRALSALLPDGYCRLGLRAIKRVLPLMEAGRTYAEAASAAGYDHALL PGGKLSPTGYLPYYGQWLQNDVVGSDDERDTNERRWGRLPNPTVHIGIGQLRRVVNELIRWHGP PAEITVELTRDLKLSPRRLAELEREQAENQRKNDKRTSLLRKLGLPASTHNLLKLRLWDEQGDV ASECPYTGEAIGLERLVSDDVDIDHLIPFSISWDDSAANKVVCMRYANREKGNRTPFEAFGHRQ GRPYDWADIAERAARLPRGKRWRFGPGARAQFEELGDFQARLLNETSWLARVAKQYLAAVTHPH RIHVLPGRLTALLRATWELNDLLPGSDDRAAKSRKDHRHHAIDALVAALTDQALLRRMANAHDD TRRKIEVLLPWPTFRIDLETRLKAMLVSHKPDHGLQARLHEDTAYGTVEHPETEDGANLVYRKT FVDISEKEIDRIRDRRLRDLVRAHVAGERQQGKTLKAAVLSFAQRRDIAGHPNGIRHVRLTKSI KPDYLVPIRDKAGRIYKSYNAGENAFVDILQAESGRWIARATTVFQANQANESHDAPAAQPIMR VFKGDMLRIDHAGAEKFVKIVRLSPSNNLLYLVEHHQAGVFQTRHDDPEDSFRWLFASFDKLRE WNAELVRIDTLGQPWRRKRGLETGSEDATRIGWTRPKKWP SEQ ID NO: 377 MERIFGFDIGTTSIGFSVIDYSSTQSAGNIQRLGVRIFPEARDPDGTPLNQQRRQKRMMRRQLR RRRIRRKALNETLHEAGFLPAYGSADWPVVMADEPYELRRRGLEEGLSAYEFGRAIYHLAQHRH FKGRELEESDTPDPDVDDEKEAANERAATLKALKNEQTTLGAWLARRPPSDRKRGIHAHRNVVA EEFERLWEVQSKFHPALKSEEMRARISDTIFAQRPVFWRKNTLGECRFMPGEPLCPKGSWLSQQ RRMLEKLNNLAIAGGNARPLDAEERDAILSKLQQQASMSWPGVRSALKALYKQRGEPGAEKSLK FNLELGGESKLLGNALEAKLADMFGPDWPAHPRKQEIRHAVHERLWAADYGETPDKKRVIILSE KDRKAHREAAANSFVADFGITGEQAAQLQALKLPTGWEPYSIPALNLFLAELEKGERFGALVNG PDWEGWRRTNFPHRNQPTGEILDKLPSPASKEERERISQLRNPTVVRTQNELRKVVNNLIGLYG KPDRIRIEVGRDVGKSKREREEIQSGIRRNEKQRKKATEDLIKNGIANPSRDDVEKWILWKEGQ ERCPYTGDQIGFNALFREGRYEVEHIWPRSRSFDNSPRNKTLCRKDVNIEKGNRMPFEAFGHDE DRWSAIQIRLQGMVSAKGGTGMSPGKVKRFLAKTMPEDFAARQLNDTRYAAKQILAQLKRLWPD MGPEAPVKVEAVTGQVTAQLRKLWTLNNILADDGEKTRADHRHHAIDALTVACTHPGMTNKLSR YWQLRDDPRAEKPALTPPWDTIRADAEKAVSEIVVSHRVRKKVSGPLHKETTYGDTGTDIKTKS GTYRQFVTRKKIESLSKGELDEIRDPRIKEIVAAHVAGRGGDPKKAFPPYPCVSPGGPEIRKVR LTSKQQLNLMAQTGNGYADLGSNHHIAIYRLPDGKADFEIVSLFDASRRLAQRNPIVQRTRADG ASFVMSLAAGEAIMIPEGSKKGIWIVQGVWASGQVVLERDTDADHSTTTRPMPNPILKDDAKKV SIDPIGRVRPSND SEQ ID NO: 378 MNKRILGLDTGTNSLGWAVVDWDEHAQSYELIKYGDVIFQEGVKIEKGIESSKAAERSGYKAIR KQYFRRRLRKIQVLKVLVKYHLCPYLSDDDLRQWHLQKQYPKSDELMLWQRTSDEEGKNPYYDR HRCLHEKLDLTVEADRYTLGRALYHLTQRRGFLSNRLDTSADNKEDGVVKSGISQLSTEMEEAG CEYLGDYFYKLYDAQGNKVRIRQRYTDRNKHYQHEFDAICEKQELSSELIEDLQRAIFFQLPLK SQRHGVGRCTFERGKPRCADSHPDYEEFRMLCFVNNIQVKGPHDLELRPLTYEEREKIEPLFFR KSKPNFDFEDIAKALAGKKNYAWIHDKEERAYKENYRMTQGVPGCPTIAQLKSIFGDDWKTGIA ETYTLIQKKNGSKSLQEMVDDVWNVLYSFSSVEKLKEFAHHKLQLDEESAEKFAKIKLSHSFAA LSLKAIRKFLPFLRKGMYYTHASFFANIPTIVGKEIWNKEQNRKYIMENVGELVFNYQPKHREV QGTIEMLIKDFLANNFELPAGATDKLYHPSMIETYPNAQRNEFGILQLGSPRTNAIRNPMAMRS LHILRRVVNQLLKESIIDENTEVHVEYARELNDANKRRAIADRQKEQDKQHKKYGDEIRKLYKE ETGKDIEPTQTDVLKFQLWEEQNHHCLYTGEQIGITDFIGSNPKFDIEHTIPQSVGGDSTQMNL TLCDNRFNREVKKAKLPTELANHEEILTRIEPWKNKYEQLVKERDKQRTFAGMDKAVKDIRIQK RHKLQMEIDYWRGKYERFTMTEVPEGFSRRQGTGIGLISRYAGLYLKSLFHQADSRNKSNVYVV KGVATAEFRKMWGLQSEYEKKCRDNHSHHCMDAITIACIGKREYDLMAEYYRMEETFKQGRGSK PKFSKPWATFTEDVLNIYKNLLVVHDTPNNMPKHTKKYVQTSIGKVLAQGDTARGSLHLDTYYG AIERDGEIRYVVRRPLSSFTKPEELENIVDETVKRTIKEAIADKNFKQAIAEPIYMNEEKGILI KKVRCFAKSVKQPINIRQHRDLSKKEYKQQYHVMNENNYLLAIYEGLVKNKVVREFEIVSYIEA AKYYKRSQDRNIFSSIVPTHSTKYGLPLKTKLLMGQLVLMFEENPDEIQVDNTKDLVKRLYKVV GIEKDGRIKFKYHQEARKEGLPIFSTPYKNNDDYAPIFRQSINNINILVDGIDFTIDILGKVTL KE SEQ ID NO: 379 MNYKMGLDIGIASVGWAVINLDLKRIEDLGVRIFDKAEHPQNGESLALPRRIARSARRRLRRRK HRLERIRRLLVSENVLTKEEMNLLFKQKKQIDVWQLRVDALERKLNNDELARVLLHLAKRRGFK SNRKSERNSKESSEFLKNIEENQSILAQYRSVGEMIVKDSKFAYHKRNKLDSYSNMIARDDLER EIKLIFEKQREFNNPVCTERLEEKYLNIWSSQRPFASKEDIEKKVGFCTFEPKEKRAPKATYTF QSFIVWEHINKLRLVSPDETRALTEIERNLLYKQAFSKNKMTYYDIRKLLNLSDDIHFKGLLYD PKSSLKQIENIRFLELDSYHKIRKCIENVYGKDGIRMFNETDIDTFGYALTIFKDDEDIVAYLQ NEYITKNGKRVSNLANKVYDKSLIDELLNLSFSKFAHLSMKAIRNILPYMEQGEIYSKACELAG YNFTGPKKKEKALLLPVIPNIANPVVMRALTQSRKVVNAIIKKYGSPVSIHIELARDLSHSFDE RKKIQKDQTENRKKNETAIKQLIEYELTKNPTGLDIVKFKLWSEQQGRCMYSLKPIELERLLEP GYVEVDHILPYSRSLDDSYANKVLVLTKENREKGNHTPVEYLGLGSERWKKFEKFVLANKQFSK KKKQNLLRLRYEETEEKEFKERNLNDTRYISKFFANFIKEHLKFADGDGGQKVYTINGKITAHL RSRWDFNKNREESDLHHAVDAVIVACATQGMIKKITEFYKAREQNKESAKKKEPIFPQPWPHFA DELKARLSKFPQESIEAFALGNYDRKKLESLRPVFVSRMPKRSVTGAAHQETLRRCVGIDEQSG KIQTAVKTKLSDIKLDKDGHFPMYQKESDPRTYEAIRQRLLEHNNDPKKAFQEPLYKPKKNGEP GPVIRTVKIIDTKNKVVHLDGSKTVAYNSNIVRTDVFEKDGKYYCVPVYTMDIMKGTLPNKAIE ANKPYSEWKEMTEEYTFQFSLFPNDLVRIVLPREKTIKTSTNEEIIIKDIFAYYKTIDSATGGL ELISHDRNFSLRGVGSKTLKRFEKYQVDVLGNIHKVKGEKRVGLAAPTNQKKGKTVDSLQSVSD SEQ ID NO: 380 MRRLGLDLGTNSIGWCLLDLGDDGEPVSIFRTGARIFSDGRDPKSLGSLKATRREARLTRRRRD REIQRQKNLINALVKYGLMPADEIQRQALAYKDPYPIRKKALDEAIDPYEMGRAIFHINQRRGF KSNRKSADNEAGVVKQSIADLEMKLGEAGARTIGEFLADRQATNDTVRARRLSGTNALYEFYPD RYMLEQEFDTLWAKQAAFNPSLYIEAARERLKEIVFFQRKLKPQEVGRCIFLSDEDRISKALPS FQRFRIYQELSNLAWIDHDGVAHRITASLALRDHLFDELEHKKKLTFKAMRAILRKQGVVDYPV GFNLESDNRDHLIGNLTSCIMRDAKKMIGSAWDRLDEEEQDSFILMLQDDQKGDDEVRSILTQQ YGLSDDVAEDCLDVRLPDGHGSLSKKAIDRILPVLRDQGLIYYDAVKEAGLGEANLYDPYAALS DKLDYYGKALAGHVMGASGKFEDSDEKRYGTISNPTVHIALNQVRAVVNELIRLHGKPDEVVIE IGRDLPMGADGKRELERFQKEGRAKNERARDELKKLGHIDSRESRQKFQLWEQLAKEPVDRCCP FTGKMMSISDLFSDKVEIEHLLPFSLTLDDSMANKTVCFRQANRDKGNRAPFDAFGNSPAGYDW QEILGRSQNLPYAKRWRFLPDAMKRFEADGGFLERQLNDTRYISRYTTEYISTIIPKNKIWVVT GRLTSLLRGFWGLNSILRGHNTDDGTPAKKSRDDHRHHAIDAIVVGMTSRGLLQKVSKAARRSE DLDLTRLFEGRIDPWDGFRDEVKKHIDAIIVSHRPRKKSQGALHNDTAYGIVEHAENGASTVVH RVPITSLGKQSDIEKVRDPLIKSALLNETAGLSGKSFENAVQKWCADNSIKSLRIVETVSIIPI TDKEGVAYKGYKGDGNAYMDIYQDPTSSKWKGEIVSRFDANQKGFIPSWQSQFPTARLIMRLRI NDLLKLQDGEIEEIYRVQRLSGSKILMAPHTEANVDARDRDKNDTFKLTSKSPGKLQSASARKV HISPTGLIREG SEQ ID NO: 381 MKNILGLDLGLSSIGWSVIRENSEEQELVAMGSRVVSLTAAELSSFTQGNGVSINSQRTQKRTQ RKGYDRYQLRRTLLRNKLDTLGMLPDDSLSYLPKLQLWGLRAKAVTQRIELNELGRVLLHLNQK RGYKSIKSDFSGDKKITDYVKTVKTRYDELKEMRLTIGELFFRRLTENAFFRCKEQVYPRQAYV EEFDCIMNCQRKFYPDILTDETIRCIRDEIIYYQRPLKSCKYLVSRCEFEKRFYLNAAGKKTEA GPKVSPRTSPLFQVCRLWESINNIVVKDRRNEIVFISAEQRAALFDFLNTHEKLKGSDLLKLLG LSKTYGYRLGEQFKTGIQGNKTRVEIERALGNYPDKKRLLQFNLQEESSSMVNTETGEIIPMIS LSFEQEPLYRLWHVLYSIDDREQLQSVLRQKFGIDDDEVLERLSAIDLVKAGFGNKSSKAIRRI LPFLQLGMNYAEACEAAGYNHSNNYTKAENEARALLDRLPAIKKNELRQPVVEKILNQMVNVVN ALMEKYGRFDEIRVELARELKQSKEERSNTYKSINKNQRENEQIAKRIVEYGVPTRSRIQKYKM WEESKHCCIYCGQPVDVGDFLRGFDVEVEHIIPKSLYFDDSFANKVCSCRSCNKEKNNRTAYDY MKSKGEKALSDYVERVNTMYTNNQISKTKWQNLLTPVDKISIDFIDRQLRESQYIARKAKEILT SICYNVTATSGSVTSFLRHVWGWDTVLHDLNFDRYKKVGLTEVIEVNHRGSVIRREQIKDWSKR FDHRHHAIDALTIACTKQAYIQRLNNLRAEEGPDFNKMSLERYIQSQPHFSVAQVREAVDRILV SFRAGKRAVTPGKRYIRKNRKRISVQSVLIPRGALSEESVYGVIHVWEKDEQGHVIQKQRAVMK YPITSINREMLDKEKVVDKRIHRILSGRLAQYNDNPKEAFAKPVYIDKECRIPIRTVRCFAKPA INTLVPLKKDDKGNPVAWVNPGNNHHVAIYRDEDGKYKERTVTFWEAVDRCRVGIPAIVTQPDT IWDNILQRNDISENVLESLPDVKWQFVLSLQQNEMFILGMNEEDYRYAMDQQDYALLNKYLYRV QKLSKSDYSFRYHTETSVEDKYDGKPNLKLSMQMGKLKRVSIKSLLGLNPHKVHISVLGEIKEI S SEQ ID NO: 382 MAEKQHRWGLDIGTNSIGWAVIALIEGRPAGLVATGSRIFSDGRNPKDGSSLAVERRGPRQMRR RRDRYLRRRDRFMQALINVGLMPGDAAARKALVTENPYVLRQRGLDQALTLPEFGRALFHLNQR RGFQSNRKTDRATAKESGKVKNAIAAFRAGMGNARTVGEALARRLEDGRPVRARMVGQGKDEHY ELYIAREWIAQEFDALWASQQRFHAEVLADAARDRLRAILLFQRKLLPVPVGKCELEPNQPRVA AALPSAQRFRLMQELNHLRVMTLADKRERPLSFQERNDLLAQLVARPKCGFDMLRKIVFGANKE AYRFTIESERRKELKGCDTAAKLAKVNALGTRWQALSLDEQDRLVCLLLDGENDAVLADALREH YGLTDAQIDTLLGLSFEDGHMRLGRSALLRVLDALESGRDEQGLPLSYDKAVVAAGYPAHTADL ENGERDALPYYGELLWRYTQDAPTAKNDAERKFGKIANPTVHIGLNQLRKLVNALIQRYGKPAQ IVVELARNLKAGLEEKERIKKQQTANLERNERIRQKLQDAGVPDNRENRLRMRLFEELGQGNGL GTPCIYSGRQISLQRLFSNDVQVDHILPFSKTLDDSFANKVLAQHDANRYKGNRGPFEAFGANR DGYAWDDIRARAAVLPRNKRNRFAETAMQDWLHNETDFLARQLTDTAYLSRVARQYLTAICSKD DVYVSPGRLTAMLRAKWGLNRVLDGVMEEQGRPAVKNRDDHRHHAIDAVVIGATDRAMLQQVAT LAARAREQDAERLIGDMPTPWPNFLEDVRAAVARCVVSHKPDHGPEGGLHNDTAYGIVAGPFED GRYRVRHRVSLFDLKPGDLSNVRCDAPLQAELEPIFEQDDARAREVALTALAERYRQRKVWLEE LMSVLPIRPRGEDGKTLPDSAPYKAYKGDSNYCYELFINERGRWDGELISTFRANQAAYRRFRN DPARFRRYTAGGRPLLMRLCINDYIAVGTAAERTIFRVVKMSENKITLAEHFEGGTLKQRDADK DDPFKYLTKSPGALRDLGARRIFVDLIGRVLDPGIKGD SEQ ID NO: 383 MIERILGVDLGISSLGWAIVEYDKDDEAANRIIDCGVRLFTAAETPKKKESPNKARREARGIRR VLNRRRVRMNMIKKLFLRAGLIQDVDLDGEGGMFYSKANRADVWELRHDGLYRLLKGDELARVL IHIAKHRGYKFIGDDEADEESGKVKKAGVVLRQNFEAAGCRTVGEWLWRERGANGKKRNKHGDY EISIHRDLLVEEVEAIFVAQQEMRSTIATDALKAAYREIAFFVRPMQRIEKMVGHCTYFPEERR APKSAPTAEKFIAISKFFSTVIIDNEGWEQKIIERKTLEELLDFAVSREKVEFRHLRKFLDLSD NEIFKGLHYKGKPKTAKKREATLFDPNEPTELEFDKVEAEKKAWISLRGAAKLREALGNEFYGR FVALGKHADEATKILTYYKDEGQKRRELTKLPLEAEMVERLVKIGFSDFLKLSLKAIRDILPAM ESGARYDEAVLMLGVPHKEKSAILPPLNKTDIDILNPTVIRAFAQFRKVANALVRKYGAFDRVH FELAREINTKGEIEDIKESQRKNEKERKEAADWIAETSFQVPLTRKNILKKRLYIQQDGRCAYT GDVIELERLFDEGYCEIDHILPRSRSADDSFANKVLCLARANQQKTDRTPYEWFGHDAARWNAF ETRTSAPSNRVRTGKGKIDRLLKKNFDENSEMAFKDRNLNDTRYMARAIKTYCEQYWVFKNSHT KAPVQVRSGKLTSVLRYQWGLESKDRESHTHHAVDAIIIAFSTQGMVQKLSEYYRFKETHREKE RPKLAVPLANFRDAVEEATRIENTETVKEGVEVKRLLISRPPRARVTGQAHEQTAKPYPRIKQV KNKKKWRLAPIDEEKFESFKADRVASANQKNFYETSTIPRVDVYHKKGKFHLVPIYLHEMVLNE LPNLSLGTNPEAMDENFFKFSIFKDDLISIQTQGTPKKPAKIIMGYFKNMHGANMVLSSINNSP CEGFTCTPVSMDKKHKDKCKLCPEENRIAGRCLQGFLDYWSQEGLRPPRKEFECDQGVKFALDV KKYQIDPLGYYYEVKQEKRLGTIPQMRSAKKLVKK SEQ ID NO: 384 MNNSIKSKPEVTIGLDLGVGSVGWAIVDNETNIIHHLGSRLFSQAKTAEDRRSFRGVRRLIRRR KYKLKRFVNLIWKYNSYFGFKNKEDILNNYQEQQKLHNTVLNLKSEALNAKIDPKALSWILHDY LKNRGHFYEDNRDFNVYPTKELAKYFDKYGYYKGIIDSKEDNDNKLEEELTKYKFSNKHWLEEV KKVLSNQTGLPEKFKEEYESLFSYVRNYSEGPGSINSVSPYGIYHLDEKEGKVVQKYNNIWDKT IGKCNIFPDEYRAPKNSPIAMIFNEINELSTIRSYSIYLTGWFINQEFKKAYLNKLLDLLIKTN GEKPIDARQFKKLREETIAESIGKETLKDVENEEKLEKEDHKWKLKGLKLNTNGKIQYNDLSSL AKFVHKLKQHLKLDFLLEDQYATLDKINFLQSLFVYLGKHLRYSNRVDSANLKEFSDSNKLFER ILQKQKDGLFKLFEQTDKDDEKILAQTHSLSTKAMLLAITRMTNLDNDEDNQKNNDKGWNFEAI KNFDQKFIDITKKNNNLSLKQNKRYLDDRFINDAILSPGVKRILREATKVFNAILKQFSEEYDV TKVVIELARELSEEKELENTKNYKKLIKKNGDKISEGLKALGISEDEIKDILKSPTKSYKFLLW LQQDHIDPYSLKEIAFDDIFTKTEKFEIDHIIPYSISFDDSSSNKLLVLAESNQAKSNQTPYEF ISSGNAGIKWEDYEAYCRKFKDGDSSLLDSTQRSKKFAKMMKTDTSSKYDIGFLARNLNDTRYA TIVFRDALEDYANNHLVEDKPMFKVVCINGSVTSFLRKNFDDSSYAKKDRDKNIHHAVDASIIS IFSNETKTLFNQLTQFADYKLFKNTDGSWKKIDPKTGVVTEVTDENWKQIRVRNQVSEIAKVIE KYIQDSNIERKARYSRKIENKTNISLFNDTVYSAKKVGYEDQIKRKNLKTLDIHESAKENKNSK VKRQFVYRKLVNVSLLNNDKLADLFAEKEDILMYRANPWVINLAEQIFNEYTENKKIKSQNVFE KYMLDLTKEFPEKFSEFLVKSMLRNKTAIIYDDKKNIVHRIKRLKMLSSELKENKLSNVIIRSK NQSGTKLSYQDTINSLALMIMRSIDPTAKKQYIRVPLNTLNLHLGDHDFDLHNMDAYLKKPKFV KYLKANEIGDEYKPWRVLTSGTLLIHKKDKKLMYISSFQNLNDVIEIKNLIETEYKENDDSDSK KKKKANRFLMTLSTILNDYILLDAKDNFDILGLSKNRIDEILNSKLGLDKIVK SEQ ID NO: 385 MGGSEVGTVPVTWRLGVDVGERSIGLAAVSYEEDKPKEILAAVSWIHDGGVGDERSGASRLALR GMARRARRLRRFRRARLRDLDMLLSELGWTPLPDKNVSPVDAWLARKRLAEEYVVDETERRRLL GYAVSHMARHRGWRNPWTTIKDLKNLPQPSDSWERTRESLEARYSVSLEPGTVGQWAGYLLQRA PGIRLNPTQQSAGRRAELSNATAFETRLRQEDVLWELRCIADVQGLPEDVVSNVIDAVFCQKRP SVPAERIGRDPLDPSQLRASRACLEFQEYRIVAAVANLRIRDGSGSRPLSLEERNAVIEALLAQ TERSLTWSDIALEILKLPNESDLTSVPEEDGPSSLAYSQFAPFDETSARIAEFIAKNRRKIPTF AQWWQEQDRTSRSDLVAALADNSIAGEEEQELLVHLPDAELEALEGLALPSGRVAYSRLTLSGL TRVMRDDGVDVHNARKTCFGVDDNWRPPLPALHEATGHPVVDRNLAILRKFLSSATMRWGPPQS IVVELARGASESRERQAEEEAARRAHRKANDRIRAELRASGLSDPSPADLVRARLLELYDCHCM YCGAPISWENSELDHIVPRTDGGSNRHENLAITCGACNKEKGRRPFASWAETSNRVQLRDVIDR VQKLKYSGNMYWTRDEFSRYKKSVVARLKRRTSDPEVIQSIESTGYAAVALRDRLLSYGEKNGV AQVAVFRGGVTAEARRWLDISIERLFSRVAIFAQSTSTKRLDRRHHAVDAVVLTTLTPGVAKTL ADARSRRVSAEFWRRPSDVNRHSTEEPQSPAYRQWKESCSGLGDLLISTAARDSIAVAAPLRLR PTGALHEETLRAFSEHTVGAAWKGAELRRIVEPEVYAAFLALTDPGGRFLKVSPSEDVLPADEN RHIVLSDRVLGPRDRVKLFPDDRGSIRVRGGAAYIASFHHARVFRWGSSHSPSFALLRVSLADL AVAGLLRDGVDVFTAELPPWTPAWRYASIALVKAVESGDAKQVGWLVPGDELDFGPEGVTTAAG DLSMFLKYFPERHWVVTGFEDDKRINLKPAFLSAEQAEVLRTERSDRPDTLTEAGEILAQFFPR CWRATVAKVLCHPGLTVIRRTALGQPRWRRGHLPYSWRPWSADPWSGGTP SEQ ID NO: 386 MHNKKNITIGFDLGIASIGWAIIDSTTSKILDWGTRTFEERKTANERRAFRSTRRNIRRKAYRN QRFINLILKYKDLFELKNISDIQRANKKDTENYEKIISFFTEIYKKCAAKHSNILEVKVKALDS KIEKLDLIWILHDYLENRGFFYDLEEENVADKYEGIEHPSILLYDFFKKNGFFKSNSSIPKDLG GYSFSNLQWVNEIKKLFEVQEINPEFSEKFLNLFTSVRDYAKGPGSEHSASEYGIFQKDEKGKV FKKYDNIWDKTIGKCSFFVEENRSPVNYPSYEIFNLLNQLINLSTDLKTTNKKIWQLSSNDRNE LLDELLKVKEKAKIISISLKKNEIKKIILKDFGFEKSDIDDQDTIEGRKIIKEEPTTKLEVTKH LLATIYSHSSDSNWININNILEFLPYLDAICIILDREKSRGQDEVLKKLTEKNIFEVLKIDREK QLDFVKSIFSNTKFNFKKIGNFSLKAIREFLPKMFEQNKNSEYLKWKDEEIRRKWEEQKSKLGK TDKKTKYLNPRIFQDEIISPGTKNTFEQAVLVLNQIIKKYSKENIIDAIIIESPREKNDKKTIE EIKKRNKKGKGKTLEKLFQILNLENKGYKLSDLETKPAKLLDRLRFYHQQDGIDLYTLDKINID QLINGSQKYEIEHIIPYSMSYDNSQANKILTEKAENLKKGKLIASEYIKRNGDEFYNKYYEKAK ELFINKYKKNKKLDSYVDLDEDSAKNRFRFLTLQDYDEFQVEFLARNLNDTRYSTKLFYHALVE HFENNEFFTYIDENSSKHKVKISTIKGHVTKYFRAKPVQKNNGPNENLNNNKPEKIEKNRENNE HHAVDAAIVAIIGNKNPQIANLLTLADNKTDKKFLLHDENYKENIETGELVKIPKFEVDKLAKV EDLKKIIQEKYEEAKKHTAIKFSRKTRTILNGGLSDETLYGFKYDEKEDKYFKIIKKKLVTSKN EELKKYFENPFGKKADGKSEYTVLMAQSHLSEFNKLKEIFEKYNGFSNKTGNAFVEYMNDLALK EPTLKAEIESAKSVEKLLYYNFKPSDQFTYHDNINNKSFKRFYKNIRIIEYKSIPIKFKILSKH DGGKSFKDTLFSLYSLVYKVYENGKESYKSIPVTSQMRNFGIDEFDFLDENLYNKEKLDIYKSD FAKPIPVNCKPVFVLKKGSILKKKSLDIDDFKETKETEEGNYYFISTISKRFNRDTAYGLKPLK LSVVKPVAEPSTNPIFKEYIPIHLDELGNEYPVKIKEHTDDEKLMCTIK

Nucleic Acids Encoding Cas9 Molecules

Nucleic acids encoding the Cas9 molecules or Cas9 polypeptides, e.g., an eaCas9 molecule or eaCas9 polypeptides are provided herein.

Exemplary nucleic acids encoding Cas9 molecules or Cas9 polypeptides are described in Cong et al., SCIENCE 2013, 399(6121):819-823; Wang et al., CELL 2013, 153(4):910-918; Mali et al., SCIENCE 2013, 399(6121):823-826; Jinek et al., SCIENCE 2012, 337(6096):816-821. Another exemplary nucleic acid encoding a Cas9 molecule or Cas9 polypeptide is shown in FIG. 8 .

In an embodiment, a nucleic acid encoding a Cas9 molecule or Cas9 polypeptide can be a synthetic nucleic acid sequence. For example, the synthetic nucleic acid molecule can be chemically modified, e.g., as described in Section VIII. In an embodiment, the Cas9 mRNA has one or more (e.g., all of the following properties: it is capped, polyadenylated, substituted with 5-methylcytidine and/or pseudouridine.

In addition, or alternatively, the synthetic nucleic acid sequence can be codon optimized, e.g., at least one non-common codon or less-common codon has been replaced by a common codon. For example, the synthetic nucleic acid can direct the synthesis of an optimized messenger mRNA, e.g., optimized for expression in a mammalian expression system, e.g., described herein.

In addition, or alternatively, a nucleic acid encoding a Cas9 molecule or Cas9 polypeptide may comprise a nuclear localization sequence (NLS). Nuclear localization sequences are known in the art.

Provided below is an exemplary codon optimized nucleic acid sequence encoding a Cas9 molecule of S. pyogenes.

(SEQ ID NO: 22)  ATGGATAAAA AGTACAGCAT CGGGCTGGAC ATCGGTACAA ACTCAGTGGG GTGGGCCGTG ATTACGGACG AGTACAAGGT ACCCTCCAAA AAATTTAAAG TGCTGGGTAA CACGGACAGA CACTCTATAA AGAAAAATCT TATTGGAGCC TTGCTGTTCG ACTCAGGCGA GACAGCCGAA GCCACAAGGT TGAAGCGGAC CGCCAGGAGG CGGTATACCA GGAGAAAGAA CCGCATATGC TACCTGCAAG AAATCTTCAG TAACGAGATG GCAAAGGTTG ACGATAGCTT TTTCCATCGC CTGGAAGAAT CCTTTCTTGT TGAGGAAGAC AAGAAGCACG AACGGCACCC CATCTTTGGC AATATTGTCG ACGAAGTGGC ATATCACGAA AAGTACCCGA CTATCTACCA CCTCAGGAAG AAGCTGGTGG ACTCTACCGA TAAGGCGGAC CTCAGACTTA TTTATTTGGC ACTCGCCCAC ATGATTAAAT TTAGAGGACA TTTCTTGATC GAGGGCGACC TGAACCCGGA CAACAGTGAC GTCGATAAGC TGTTCATCCA ACTTGTGCAG ACCTACAATC AACTGTTCGA AGAAAACCCT ATAAATGCTT CAGGAGTCGA CGCTAAAGCA ATCCTGTCCG CGCGCCTCTC AAAATCTAGA AGACTTGAGA ATCTGATTGC TCAGTTGCCC GGGGAAAAGA AAAATGGATT GTTTGGCAAC CTGATCGCCC TCAGTCTCGG ACTGACCCCA AATTTCAAAA GTAACTTCGA CCTGGCCGAA GACGCTAAGC TCCAGCTGTC CAAGGACACA TACGATGACG ACCTCGACAA TCTGCTGGCC CAGATTGGGG ATCAGTACGC CGATCTCTTT TTGGCAGCAA AGAACCTGTC CGACGCCATC CTGTTGAGCG ATATCTTGAG AGTGAACACC GAAATTACTA AAGCACCCCT TAGCGCATCT ATGATCAAGC GGTACGACGA GCATCATCAG GATCTGACCC TGCTGAAGGC TCTTGTGAGG CAACAGCTCC CCGAAAAATA CAAGGAAATC TTCTTTGACC AGAGCAAAAA CGGCTACGCT GGCTATATAG ATGGTGGGGC CAGTCAGGAG GAATTCTATA AATTCATCAA GCCCATTCTC GAGAAAATGG ACGGCACAGA GGAGTTGCTG GTCAAACTTA ACAGGGAGGA CCTGCTGCGG AAGCAGCGGA CCTTTGACAA CGGGTCTATC CCCCACCAGA TTCATCTGGG CGAACTGCAC GCAATCCTGA GGAGGCAGGA GGATTTTTAT CCTTTTCTTA AAGATAACCG CGAGAAAATA GAAAAGATTC TTACATTCAG GATCCCGTAC TACGTGGGAC CTCTCGCCCG GGGCAATTCA CGGTTTGCCT GGATGACAAG GAAGTCAGAG GAGACTATTA CACCTTGGAA CTTCGAAGAA GTGGTGGACA AGGGTGCATC TGCCCAGTCT TTCATCGAGC GGATGACAAA TTTTGACAAG AACCTCCCTA ATGAGAAGGT GCTGCCCAAA CATTCTCTGC TCTACGAGTA CTTTACCGTC TACAATGAAC TGACTAAAGT CAAGTACGTC ACCGAGGGAA TGAGGAAGCC GGCATTCCTT AGTGGAGAAC AGAAGAAGGC GATTGTAGAC CTGTTGTTCA AGACCAACAG GAAGGTGACT GTGAAGCAAC TTAAAGAAGA CTACTTTAAG AAGATCGAAT GTTTTGACAG TGTGGAAATT TCAGGGGTTG AAGACCGCTT CAATGCGTCA TTGGGGACTT ACCATGATCT TCTCAAGATC ATAAAGGACA AAGACTTCCT GGACAACGAA GAAAATGAGG ATATTCTCGA AGACATCGTC CTCACCCTGA CCCTGTTCGA AGACAGGGAA ATGATAGAAG AGCGCTTGAA AACCTATGCC CACCTCTTCG ACGATAAAGT TATGAAGCAG CTGAAGCGCA GGAGATACAC AGGATGGGGA AGATTGTCAA GGAAGCTGAT CAATGGAATT AGGGATAAAC AGAGTGGCAA GACCATACTG GATTTCCTCA AATCTGATGG CTTCGCCAAT AGGAACTTCA TGCAACTGAT TCACGATGAC TCTCTTACCT TCAAGGAGGA CATTCAAAAG GCTCAGGTGA GCGGGCAGGG AGACTCCCTT CATGAACACA TCGCGAATTT GGCAGGTTCC CCCGCTATTA AAAAGGGCAT CCTTCAAACT GTCAAGGTGG TGGATGAATT GGTCAAGGTA ATGGGCAGAC ATAAGCCAGA AAATATTGTG ATCGAGATGG CCCGCGAAAA CCAGACCACA CAGAAGGGCC AGAAAAATAG TAGAGAGCGG ATGAAGAGGA TCGAGGAGGG CATCAAAGAG CTGGGATCTC AGATTGTCAA AGAACACCCC GTAGAAAACA CACAGCTGCA GAACGAAAAA TTGTACTTGT ACTATCTGCA GAACGGCAGA GACATGTACG TCGACCAAGA ACTTGATATT AATAGACTGT CCGACTATGA CGTAGACCAT ATCGTGCCCC AGTCCTTCCT GAAGGACGAC TCCATTGATA ACAAAGTCTT GACAAGAAGC GACAAGAACA GGGGTAAAAG TGATAATGTG CCTAGCGAGG AGGTGGTGAA AAAAATGAAG AACTACTGGC GACAGCTGCT TAATGCAAAG CTCATTACAC AACGGAAGTT CGATAATCTG ACGAAAGCAG AGAGAGGTGG CTTGTCTGAG TTGGACAAGG CAGGGTTTAT TAAGCGGCAG CTGGTGGAAA CTAGGCAGAT CACAAAGCAC GTGGCGCAGA TTTTGGACAG CCGGATGAAC ACAAAATACG ACGAAAATGA TAAACTGATA CGAGAGGTCA AAGTTATCAC GCTGAAAAGC AAGCTGGTGT CCGATTTTCG GAAAGACTTC CAGTTCTACA AAGTTCGCGA GATTAATAAC TACCATCATG CTCACGATGC GTACCTGAAC GCTGTTGTCG GGACCGCCTT GATAAAGAAG TACCCAAAGC TGGAATCCGA GTTCGTATAC GGGGATTACA AAGTGTACGA TGTGAGGAAA ATGATAGCCA AGTCCGAGCA GGAGATTGGA AAGGCCACAG CTAAGTACTT CTTTTATTCT AACATCATGA ATTTTTTTAA GACGGAAATT ACCCTGGCCA ACGGAGAGAT CAGAAAGCGG CCCCTTATAG AGACAAATGG TGAAACAGGT GAAATCGTCT GGGATAAGGG CAGGGATTTC GCTACTGTGA GGAAGGTGCT GAGTATGCCA CAGGTAAATA TCGTGAAAAA AACCGAAGTA CAGACCGGAG GATTTTCCAA GGAAAGCATT TTGCCTAAAA GAAACTCAGA CAAGCTCATC GCCCGCAAGA AAGATTGGGA CCCTAAGAAA TACGGGGGAT TTGACTCACC CACCGTAGCC TATTCTGTGC TGGTGGTAGC TAAGGTGGAA AAAGGAAAGT CTAAGAAGCT GAAGTCCGTG AAGGAACTCT TGGGAATCAC TATCATGGAA AGATCATCCT TTGAAAAGAA CCCTATCGAT TTCCTGGAGG CTAAGGGTTA CAAGGAGGTC AAGAAAGACC TCATCATTAA ACTGCCAAAA TACTCTCTCT TCGAGCTGGA AAATGGCAGG AAGAGAATGT TGGCCAGCGC CGGAGAGCTG CAAAAGGGAA ACGAGCTTGC TCTGCCCTCC AAATATGTTA ATTTTCTCTA TCTCGCTTCC CACTATGAAA AGCTGAAAGG GTCTCCCGAA GATAACGAGC AGAAGCAGCT GTTCGTCGAA CAGCACAAGC ACTATCTGGA TGAAATAATC GAACAAATAA GCGAGTTCAG CAAAAGGGTT ATCCTGGCGG ATGCTAATTT GGACAAAGTA CTGTCTGCTT ATAACAAGCA CCGGGATAAG CCTATTAGGG AACAAGCCGA GAATATAATT CACCTCTTTA CACTCACGAA TCTCGGAGCC CCCGCCGCCT TCAAATACTT TGATACGACT ATCGACCGGA AACGGTATAC CAGTAGCAAA GAGGTCCTCG ATGCCACCCT CATCCACCAG TCAATTACTG GCCTGTACGA AACACGGATC GACCTCTCTC AACTGGGCGG CGAGTAG

Provided below is the corresponding amino acid sequence of a S. pyogenes Cas9 molecule.

(SEQ ID NO: 23) MDKKYSIGLDIGTNSVGWAVITDEYKVPSKKFKVLGNTDRHSIKKNLIGALLFDSGETAEATRL KRTARRRYTRRKNRICYLQEIFSNEMAKVDDSFFHRLEESFLVEEDKKHERHPIFGNIVDEVAY HEKYPTIYHLRKKLVDSTDKADLRLIYLALAHMIKFRGHFLIEGDLNPDNSDVDKLFIQLVQTY NQLFEENPINASGVDAKAILSARLSKSRRLENLIAQLPGEKKNGLFGNLIALSLGLTPNFKSNF DLAEDAKLQLSKDTYDDDLDNLLAQIGDQYADLFLAAKNLSDAILLSDILRVNTEITKAPLSAS MIKRYDEHHQDLTLLKALVRQQLPEKYKEIFFDQSKNGYAGYIDGGASQEEFYKFIKPILEKMD GTEELLVKLNREDLLRKQRTFDNGSIPHQIHLGELHAILRRQEDFYPFLKDNREKIEKILTFRI PYYVGPLARGNSRFAWMTRKSEETITPWNFEEVVDKGASAQSFIERMTNFDKNLPNEKVLPKHS LLYEYFTVYNELTKVKYVTEGMRKPAFLSGEQKKAIVDLLFKTNRKVTVKQLKEDYFKKIECFD SVEISGVEDRFNASLGTYHDLLKIIKDKDFLDNEENEDILEDIVLTLTLFEDREMIEERLKTYA HLFDDKVMKQLKRRRYTGWGRLSRKLINGIRDKQSGKTILDFLKSDGFANRNFMQLIHDDSLTF KEDIQKAQVSGQGDSLHEHIANLAGSPAIKKGILQTVKVVDELVKVMGRHKPENIVIEMARENQ TTQKGQKNSRERMKRIEEGIKELGSQILKEHPVENTQLQNEKLYLYYLQNGRDMYVDQELDINR LSDYDVDHIVPQSFLKDDSIDNKVLTRSDKNRGKSDNVPSEEVVKKMKNYWRQLLNAKLITQRK FDNLTKAERGGLSELDKAGFIKRQLVETRQITKHVAQILDSRMNTKYDENDKLIREVKVITLKS KLVSDFRKDFQFYKVREINNYHHAHDAYLNAVVGTALIKKYPKLESEFVYGDYKVYDVRKMIAK SEQEIGKATAKYFFYSNIMNFFKTEITLANGEIRKRPLIETNGETGEIVWDKGRDFATVRKVLS MPQVNIVKKTEVQTGGFSKESILPKRNSDKLIARKKDWDPKKYGGFDSPTVAYSVLVVAKVEKG KSKKLKSVKELLGITIMERSSFEKNPIDFLEAKGYKEVKKDLIIKLPKYSLFELENGRKRMLAS AGELQKGNELALPSKYVNFLYLASHYEKLKGSPEDNEQKQLFVEQHKHYLDEIIEQISEFSKRV ILADANLDKVLSAYNKHRDKPIREQAENIIHLFTLTNLGAPAAFKYFDTTIDRKRYTSTKEVLD ATLIHQSITGLYETRIDLSQLGGD*

Provided below is an exemplary codon optimized nucleic acid sequence encoding a Cas9 molecule of N. meningitidis.

(SEQ ID NO: 24) ATGGCCGCCTTCAAGCCCAACCCCATCAACTACATCCTGGGCCTGGACATCGGCATCGCCAGCG TGGGCTGGGCCATGGTGGAGATCGACGAGGACGAGAACCCCATCTGCCTGATCGACCTGGGTGT GCGCGTGTTCGAGCGCGCTGAGGTGCCCAAGACTGGTGACAGTCTGGCTATGGCTCGCCGGCTT GCTCGCTCTGTTCGGCGCCTTACTCGCCGGCGCGCTCACCGCCTTCTGCGCGCTCGCCGCCTGC TGAAGCGCGAGGGTGTGCTGCAGGCTGCCGACTTCGACGAGAACGGCCTGATCAAGAGCCTGCC CAACACTCCTTGGCAGCTGCGCGCTGCCGCTCTGGACCGCAAGCTGACTCCTCTGGAGTGGAGC GCCGTGCTGCTGCACCTGATCAAGCACCGCGGCTACCTGAGCCAGCGCAAGAACGAGGGCGAGA CCGCCGACAAGGAGCTGGGTGCTCTGCTGAAGGGCGTGGCCGACAACGCCCACGCCCTGCAGAC TGGTGACTTCCGCACTCCTGCTGAGCTGGCCCTGAACAAGTTCGAGAAGGAGAGCGGCCACATC CGCAACCAGCGCGGCGACTACAGCCACACCTTCAGCCGCAAGGACCTGCAGGCCGAGCTGATCC TGCTGTTCGAGAAGCAGAAGGAGTTCGGCAACCCCCACGTGAGCGGCGGCCTGAAGGAGGGCAT CGAGACCCTGCTGATGACCCAGCGCCCCGCCCTGAGCGGCGACGCCGTGCAGAAGATGCTGGGC CACTGCACCTTCGAGCCAGCCGAGCCCAAGGCCGCCAAGAACACCTACACCGCCGAGCGCTTCA TCTGGCTGACCAAGCTGAACAACCTGCGCATCCTGGAGCAGGGCAGCGAGCGCCCCCTGACCGA CACCGAGCGCGCCACCCTGATGGACGAGCCCTACCGCAAGAGCAAGCTGACCTACGCCCAGGCC CGCAAGCTGCTGGGTCTGGAGGACACCGCCTTCTTCAAGGGCCTGCGCTACGGCAAGGACAACG CCGAGGCCAGCACCCTGATGGAGATGAAGGCCTACCACGCCATCAGCCGCGCCCTGGAGAAGGA GGGCCTGAAGGACAAGAAGAGTCCTCTGAACCTGAGCCCCGAGCTGCAGGACGAGATCGGCACC GCCTTCAGCCTGTTCAAGACCGACGAGGACATCACCGGCCGCCTGAAGGACCGCATCCAGCCCG AGATCCTGGAGGCCCTGCTGAAGCACATCAGCTTCGACAAGTTCGTGCAGATCAGCCTGAAGGC CCTGCGCCGCATCGTGCCCCTGATGGAGCAGGGCAAGCGCTACGACGAGGCCTGCGCCGAGATC TACGGCGACCACTACGGCAAGAAGAACACCGAGGAGAAGATCTACCTGCCTCCTATCCCCGCCG ACGAGATCCGCAACCCCGTGGTGCTGCGCGCCCTGAGCCAGGCCCGCAAGGTGATCAACGGCGT GGTGCGCCGCTACGGCAGCCCCGCCCGCATCCACATCGAGACCGCCCGCGAGGTGGGCAAGAGC TTCAAGGACCGCAAGGAGATCGAGAAGCGCCAGGAGGAGAACCGCAAGGACCGCGAGAAGGCCG CCGCCAAGTTCCGCGAGTACTTCCCCAACTTCGTGGGCGAGCCCAAGAGCAAGGACATCCTGAA GCTGCGCCTGTACGAGCAGCAGCACGGCAAGTGCCTGTACAGCGGCAAGGAGATCAACCTGGGC CGCCTGAACGAGAAGGGCTACGTGGAGATCGACCACGCCCTGCCCTTCAGCCGCACCTGGGACG ACAGCTTCAACAACAAGGTGCTGGTGCTGGGCAGCGAGAACCAGAACAAGGGCAACCAGACCCC CTACGAGTACTTCAACGGCAAGGACAACAGCCGCGAGTGGCAGGAGTTCAAGGCCCGCGTGGAG ACCAGCCGCTTCCCCCGCAGCAAGAAGCAGCGCATCCTGCTGCAGAAGTTCGACGAGGACGGCT TCAAGGAGCGCAACCTGAACGACACCCGCTACGTGAACCGCTTCCTGTGCCAGTTCGTGGCCGA CCGCATGCGCCTGACCGGCAAGGGCAAGAAGCGCGTGTTCGCCAGCAACGGCCAGATCACCAAC CTGCTGCGCGGCTTCTGGGGCCTGCGCAAGGTGCGCGCCGAGAACGACCGCCACCACGCCCTGG ACGCCGTGGTGGTGGCCTGCAGCACCGTGGCCATGCAGCAGAAGATCACCCGCTTCGTGCGCTA CAAGGAGATGAACGCCTTCGACGGTAAAACCATCGACAAGGAGACCGGCGAGGTGCTGCACCAG AAGACCCACTTCCCCCAGCCCTGGGAGTTCTTCGCCCAGGAGGTGATGATCCGCGTGTTCGGCA AGCCCGACGGCAAGCCCGAGTTCGAGGAGGCCGACACCCCCGAGAAGCTGCGCACCCTGCTGGC CGAGAAGCTGAGCAGCCGCCCTGAGGCCGTGCACGAGTACGTGACTCCTCTGTTCGTGAGCCGC GCCCCCAACCGCAAGATGAGCGGTCAGGGTCACATGGAGACCGTGAAGAGCGCCAAGCGCCTGG ACGAGGGCGTGAGCGTGCTGCGCGTGCCCCTGACCCAGCTGAAGCTGAAGGACCTGGAGAAGAT GGTGAACCGCGAGCGCGAGCCCAAGCTGTACGAGGCCCTGAAGGCCCGCCTGGAGGCCCACAAG GACGACCCCGCCAAGGCCTTCGCCGAGCCCTTCTACAAGTACGACAAGGCCGGCAACCGCACCC AGCAGGTGAAGGCCGTGCGCGTGGAGCAGGTGCAGAAGACCGGCGTGTGGGTGCGCAACCACAA CGGCATCGCCGACAACGCCACCATGGTGCGCGTGGACGTGTTCGAGAAGGGCGACAAGTACTAC CTGGTGCCCATCTACAGCTGGCAGGTGGCCAAGGGCATCCTGCCCGACCGCGCCGTGGTGCAGG GCAAGGACGAGGAGGACTGGCAGCTGATCGACGACAGCTTCAACTTCAAGTTCAGCCTGCACCC CAACGACCTGGTGGAGGTGATCACCAAGAAGGCCCGCATGTTCGGCTACTTCGCCAGCTGCCAC CGCGGCACCGGCAACATCAACATCCGCATCCACGACCTGGACCACAAGATCGGCAAGAACGGCA TCCTGGAGGGCATCGGCGTGAAGACCGCCCTGAGCTTCCAGAAGTACCAGATCGACGAGCTGGG CAAGGAGATCCGCCCCTGCCGCCTGAAGAAGCGCCCTCCTGTGCGCTAA

Provided below is the corresponding amino acid sequence of a N. meningitidis Cas9 molecule.

(SEQ ID NO: 25) MAAFKPNPINYILGLDIGIASVGWAMVEIDEDENPICLIDLGVRVFERAEVPKTGDSLAMARRL ARSVRRLTRRRAHRLLRARRLLKREGVLQAADFDENGLIKSLPNTPWQLRAAALDRKLTPLEWS AVLLHLIKHRGYLSQRKNEGETADKELGALLKGVADNAHALQTGDFRTPAELALNKFEKESGHI RNQRGDYSHTFSRKDLQAELILLFEKQKEFGNPHVSGGLKEGIETLLMTQRPALSGDAVQKMLG HCTFEPAEPKAAKNTYTAERFIWLTKLNNLRILEQGSERPLTDTERATLMDEPYRKSKLTYAQA RKLLGLEDTAFFKGLRYGKDNAEASTLMEMKAYHAISRALEKEGLKDKKSPLNLSPELQDEIGT AFSLFKTDEDITGRLKDRIQPEILEALLKHISFDKFVQISLKALRRIVPLMEQGKRYDEACAEI YGDHYGKKNTEEKIYLPPIPADEIRNPVVLRALSQARKVINGVVRRYGSPARIHIETAREVGKS FKDRKEIEKRQEENRKDREKAAAKFREYFPNFVGEPKSKDILKLRLYEQQHGKCLYSGKEINLG RLNEKGYVEIDHALPFSRTWDDSFNNKVLVLGSENQNKGNQTPYEYFNGKDNSREWQEFKARVE TSRFPRSKKQRILLQKFDEDGFKERNLNDTRYVNRFLCQFVADRMRLTGKGKKRVFASNGQITN LLRGFWGLRKVRAENDRHHALDAVVVACSTVAMQQKITRFVRYKEMNAFDGKTIDKETGEVLHQ KTHFPQPWEFFAQEVMIRVFGKPDGKPEFEEADTPEKLRTLLAEKLSSRPEAVHEYVTPLFVSR APNRKMSGQGHMETVKSAKRLDEGVSVLRVPLTQLKLKDLEKMVNREREPKLYEALKARLEAHK DDPAKAFAEPFYKYDKAGNRTQQVKAVRVEQVQKTGVWVRNHNGIADNATMVRVDVFEKGDKYY LVPIYSWQVAKGILPDRAVVQGKDEEDWQLIDDSFNFKFSLHPNDLVEVITKKARMFGYFASCH RGTGNINIRIHDLDHKIGKNGILEGIGVKTALSFQKYQIDELGKEIRPCRLKKRPPVR*

Provided below is an amino acid sequence of a S. aureus Cas9 molecule.

(SEQ ID NO: 26) MKRNYILGLDIGITSVGYGIIDYETRDVIDAGVRLFKEANVENNEGRRSKRGARRLKRRRRHRI QRVKKLLFDYNLLTDHSELSGINPYEARVKGLSQKLSEEEFSAALLHLAKRRGVHNVNEVEEDT GNELSTKEQISRNSKALEEKYVAELQLERLKKDGEVRGSINRFKTSDYVKEAKQLLKVQKAYHQ LDQSFIDTYIDLLETRRTYYEGPGEGSPFGWKDIKEWYEMLMGHCTYFPEELRSVKYAYNADLY NALNDLNNLVITRDENEKLEYYEKFQIIENVFKQKKKPTLKQIAKEILVNEEDIKGYRVTSTGK PEFTNLKVYHDIKDITARKEIIENAELLDQIAKILTIYQSSEDIQEELTNLNSELTQEEIEQIS NLKGYTGTHNLSLKAINLILDELWHTNDNQIAIFNRLKLVPKKVDLSQQKEIPTTLVDDFILSP VVKRSFIQSIKVINAIIKKYGLPNDIIIELAREKNSKDAQKMINEMQKRNRQTNERIEEIIRTT GKENAKYLIEKIKLHDMQEGKCLYSLEAIPLEDLLNNPFNYEVDHIIPRSVSFDNSFNNKVLVK QEENSKKGNRTPFQYLSSSDSKISYETFKKHILNLAKGKGRISKTKKEYLLEERDINRFSVQKD FINRNLVDTRYATRGLMNLLRSYFRVNNLDVKVKSINGGFTSFLRRKWKFKKERNKGYKHHAED ALIIANADFIFKEWKKLDKAKKVMENQMFEEKQAESMPEIETEQEYKEIFITPHQIKHIKDFKD YKYSHRVDKKPNRELINDTLYSTRKDDKGNTLIVNNLNGLYDKDNDKLKKLINKSPEKLLMYHH DPQTYQKLKLIMEQYGDEKNPLYKYYEETGNYLTKYSKKDNGPVIKKIKYYGNKLNAHLDITDD YPNSRNKVVKLSLKPYRFDVYLDNGVYKFVTVKNLDVIKKENYYEVNSKCYEEAKKLKKISNOA EFIASEYNNDLIKINGELYRVIGVNNDLLNRIEVNMIDITYREYLENMNDKRPPRIIKTIASKT QSIKKYSTDILGNLYEVKSKKHPQIIKKG*

Provided below is an exemplary codon optimized nucleic acid sequence encoding a Cas9 molecule of S. aureus Cas9.

(SEQ ID NO: 39) ATGAAAAGGAACTACATTCTGGGGCTGGACATCGGGATTACAAGCGTGGGGTATGGGATTATTG ACTATGAAACAAGGGACGTGATCGACGCAGGCGTCAGACTGTTCAAGGAGGCCAACGTGGAAAA CAATGAGGGACGGAGAAGCAAGAGGGGAGCCAGGCGCCTGAAACGACGGAGAAGGCACAGAATC CAGAGGGTGAAGAAACTGCTGTTCGATTACAACCTGCTGACCGACCATTCTGAGCTGAGTGGAA TTAATCCTTATGAAGCCAGGGTGAAAGGCCTGAGTCAGAAGCTGTCAGAGGAAGAGTTTTCCGC AGCTCTGCTGCACCTGGCTAAGCGCCGAGGAGTGCATAACGTCAATGAGGTGGAAGAGGACACC GGCAACGAGCTGTCTACAAAGGAACAGATCTCACGCAATAGCAAAGCTCTGGAAGAGAAGTATG TCGCAGAGCTGCAGCTGGAACGGCTGAAGAAAGATGGCGAGGTGAGAGGGTCAATTAATAGGTT CAAGACAAGCGACTACGTCAAAGAAGCCAAGCAGCTGCTGAAAGTGCAGAAGGCTTACCACCAG CTGGATCAGAGCTTCATCGATACTTATATCGACCTGCTGGAGACTCGGAGAACCTACTATGAGG GACCAGGAGAAGGGAGCCCCTTCGGATGGAAAGACATCAAGGAATGGTACGAGATGCTGATGGG ACATTGCACCTATTTTCCAGAAGAGCTGAGAAGCGTCAAGTACGCTTATAACGCAGATCTGTAC AACGCCCTGAATGACCTGAACAACCTGGTCATCACCAGGGATGAAAACGAGAAACTGGAATACT ATGAGAAGTTCCAGATCATCGAAAACGTGTTTAAGCAGAAGAAAAAGCCTACACTGAAACAGAT TGCTAAGGAGATCCTGGTCAACGAAGAGGACATCAAGGGCTACCGGGTGACAAGCACTGGAAAA CCAGAGTTCACCAATCTGAAAGTGTATCACGATATTAAGGACATCACAGCACGGAAAGAAATCA TTGAGAACGCCGAACTGCTGGATCAGATTGCTAAGATCCTGACTATCTACCAGAGCTCCGAGGA CATCCAGGAAGAGCTGACTAACCTGAACAGCGAGCTGACCCAGGAAGAGATCGAACAGATTAGT AATCTGAAGGGGTACACCGGAACACACAACCTGTCCCTGAAAGCTATCAATCTGATTCTGGATG AGCTGTGGCATACAAACGACAATCAGATTGCAATCTTTAACCGGCTGAAGCTGGTCCCAAAAAA GGTGGACCTGAGTCAGCAGAAAGAGATCCCAACCACACTGGTGGACGATTTCATTCTGTCACCC GTGGTCAAGCGGAGCTTCATCCAGAGCATCAAAGTGATCAACGCCATCATCAAGAAGTACGGCC TGCCCAATGATATCATTATCGAGCTGGCTAGGGAGAAGAACAGCAAGGACGCACAGAAGATGAT CAATGAGATGCAGAAACGAAACCGGCAGACCAATGAACGCATTGAAGAGATTATCCGAACTACC GGGAAAGAGAACGCAAAGTACCTGATTGAAAAAATCAAGCTGCACGATATGCAGGAGGGAAAGT GTCTGTATTCTCTGGAGGCCATCCCCCTGGAGGACCTGCTGAACAATCCATTCAACTACGAGGT CGATCATATTATCCCCAGAAGCGTGTCCTTCGACAATTCCTTTAACAACAAGGTGCTGGTCAAG CAGGAAGAGAACTCTAAAAAGGGCAATAGGACTCCTTTCCAGTACCTGTCTAGTTCAGATTCCA AGATCTCTTACGAAACCTTTAAAAAGCACATTCTGAATCTGGCCAAAGGAAAGGGCCGCATCAG CAAGACCAAAAAGGAGTACCTGCTGGAAGAGCGGGACATCAACAGATTCTCCGTCCAGAAGGAT TTTATTAACCGGAATCTGGTGGACACAAGATACGCTACTCGCGGCCTGATGAATCTGCTGCGAT CCTATTTCCGGGTGAACAATCTGGATGTGAAAGTCAAGTCCATCAACGGCGGGTTCACATCTTT TCTGAGGCGCAAATGGAAGTTTAAAAAGGAGCGCAACAAAGGGTACAAGCACCATGCCGAAGAT GCTCTGATTATCGCAAATGCCGACTTCATCTTTAAGGAGTGGAAAAAGCTGGACAAAGCCAAGA AAGTGATGGAGAACCAGATGTTCGAAGAGAAGCAGGCCGAATCTATGCCCGAAATCGAGACAGA ACAGGAGTACAAGGAGATTTTCATCACTCCTCACCAGATCAAGCATATCAAGGATTTCAAGGAC TACAAGTACTCTCACCGGGTGGATAAAAAGCCCAACAGAGAGCTGATCAATGACACCCTGTATA GTACAAGAAAAGACGATAAGGGGAATACCCTGATTGTGAACAATCTGAACGGACTGTACGACAA AGATAATGACAAGCTGAAAAAGCTGATCAACAAAAGTCCCGAGAAGCTGCTGATGTACCACCAT GATCCTCAGACATATCAGAAACTGAAGCTGATTATGGAGCAGTACGGCGACGAGAAGAACCCAC TGTATAAGTACTATGAAGAGACTGGGAACTACCTGACCAAGTATAGCAAAAAGGATAATGGCCC CGTGATCAAGAAGATCAAGTACTATGGGAACAAGCTGAATGCCCATCTGGACATCACAGACGAT TACCCTAACAGTCGCAACAAGGTGGTCAAGCTGTCACTGAAGCCATACAGATTCGATGTCTATC TGGACAACGGCGTGTATAAATTTGTGACTGTCAAGAATCTGGATGTCATCAAAAAGGAGAACTA CTATGAAGTGAATAGCAAGTGCTACGAAGAGGCTAAAAAGCTGAAAAAGATTAGCAACCAGGCA GAGTTCATCGCCTCCTTTTACAACAACGACCTGATTAAGATCAATGGCGAACTGTATAGGGTCA TCGGGGTGAACAATGATCTGCTGAACCGCATTGAAGTGAATATGATTGACATCACTTACCGAGA GTATCTGGAAAACATGAATGATAAGCGCCCCCCTCGAATTATCAAAACAATTGCCTCTAAGACT CAGAGTATCAAAAAGTACTCAACCGACATTCTGGGAAACCTGTATGAGGTGAAGAGCAAAAAGC ACCCTCAGATTATCAAAAAGGGC

If any of the above Cas9 sequences are fused with a peptide or polypeptide at the C-terminus, it is understood that the stop codon will be removed.

Other Cas Molecules and Cas Polypeptides

Various types of Cas molecules or Cas polypeptides can be used to practice the inventions disclosed herein. In some embodiments, Cas molecules of Type II Cas systems are used. In other embodiments, Cas molecules of other Cas systems are used. For example, Type I or Type III Cas molecules may be used. Exemplary Cas molecules (and Cas systems) are described, e.g., in Haft et al., PLOS COMPUTATIONAL BIOLOGY 2005, 1(6): e60 and Makarova et al., NATURE REVIEW MICROBIOLOGY 2011, 9:467-477, the contents of both references are incorporated herein by reference in their entirety. Exemplary Cas molecules (and Cas systems) are also shown in Table 33.

TABLE 33 Cas Systems Structure of Families (and encoded superfamily) protein of Gene System type Name from (PDB encoded name^(‡) or subtype Haft et al.^(§) accessions)^(¶) protein^(#)** Representatives cas1 Type I cas1 3GOD, 3LFX COG1518 SERP2463, SPy1047 Type II and 2YZS and ygbT Type III cas2 Type I cas2 2IVY, 2I8E and COG1343 and SERP2462, SPy1048, Type II 3EXC COG3512 SPy1723 (N-terminal Type III domain) and ygbF cas3′ Type I^(‡‡) cas3 NA COG1203 APE1232 and ygcB cas3″ Subtype I-A NA NA COG2254 APE1231 and BH0336 Subtype I-B cas4 Subtype I-A cas4 and csa1 NA COG1468 APE1239 and BH0340 Subtype I-B Subtype I-C Subtype I-D Subtype II- B cas5 Subtype I-A cas5a, cas5d, 3KG4 COG1688 APE1234, BH0337, Subtype I-B cas5e, cas5h, (RAMP) devS and ygcI Subtype I-C cas5p, cas5t Subtype I-E and cmx5 cas6 Subtype I-A cas6 and cmx6 3I4H COG1583 and PF1131 and slr7014 Subtype I-B COG5551 Subtype I-D (RAMP) Subtype III-A Subtype III-B cas6e Subtype I-E cse3 1WJ9 (RAMP) ygcH cas6f Subtype I-F csy4 2XLJ (RAMP) y1727 cas7 Subtype I-A csa2, csd2, NA COG1857 and devR and ygcJ Subtype I-B cse4, csh2, COG3649 Subtype I-C csp1 and cst2 (RAMP) Subtype I-E cas8a1 Subtype I- cmx1, cst1, NA BH0338-like LA3191^(§§) and A^(‡‡) csx8, csx13 PG2018^(§§) and CXXC- CXXC cas8a2 Subtype I- csa4 and csx9 NA PH0918 AF0070, AF1873, A^(‡‡) MJ0385, PF0637, PH0918 and SSO1401 cas8b Subtype I- csh1 and NA BH0338-like MTH1090 and B^(‡‡) TM1802 TM1802 cas8c Subtype I- csd1 and csp2 NA BH0338-like BH0338 C^(‡‡) cas9 Type II^(‡‡) csn1 and csx12 NA COG3513 FTN_0757 and SPy1046 cas10 Type III^(‡‡) cmr2, csm1 NA COG1353 MTH326, Rv2823c^(§§) and csx111 and TM1794^(§§) cas10d Subtype I- csc3 NA COG1353 slr7011 D^(‡‡) csy1 Subtype I- csy1 NA y1724-like y1724 F^(‡‡) csy2 Subtype I-F csy2 NA (RAMP) y1725 csy3 Subtype I-F csy3 NA (RAMP) y1726 cse1 Subtype I- cse1 NA YgcL-like ygcL E^(‡‡) cse2 Subtype I-E cse2 2ZCA YgcK-like ygcK csc1 Subtype I-D csc1 NA alr1563-like alr1563 (RAMP) csc2 Subtype I-D csc1 and csc2 NA COG1337 slr7012 (RAMP) csa5 Subtype I-A csa5 NA AF1870 AF1870, MJ0380, PF0643 and SSO1398 csn2 Subtype II- csn2 NA SPy1049-like SPy1049 A csm2 Subtype III- csm2 NA COG1421 MTH1081 and A^(‡‡) SERP2460 csm3 Subtype III- csc2 and csm3 NA COG1337 MTH1080 and A (RAMP) SERP2459 csm4 Subtype III- csm4 NA COG1567 MTH1079 and A (RAMP) SERP2458 csm5 Subtype III- csm5 NA COG1332 MTH1078 and A (RAMP) SERP2457 csm6 Subtype III- APE2256 and 2WTE COG1517 APE2256 and A csm6 SSO1445 cmr1 Subtype III- cmr1 NA COG1367 PF1130 B (RAMP) cmr3 Subtype III- cmr3 NA COG1769 PF1128 B (RAMP) cmr4 Subtype III- cmr4 NA COG1336 PF1126 B (RAMP) cmr5 Subtype III- cmr5 2ZOP and 2OEB COG3337 MTH324 and PF1125 B^(‡‡) cmr6 Subtype III- cmr6 NA COG1604 PF1124 B (RAMP) csb1 Subtype I-U GSU0053 NA (RAMP) Balac_1306 and GSU0053 csb2 Subtype I- NA NA (RAMP) Balac_1305 and U^(§§) GSU0054 csb3 Subtype I-U NA NA (RAMP) Balac_1303^(§§) csx17 Subtype I-U NA NA NA Btus_2683 csx14 Subtype I-U NA NA NA GSU0052 csx10 Subtype I-U csx10 NA (RAMP) Caur_2274 csx16 Subtype III- VVA1548 NA NA VVA1548 U csaX Subtype III- csaX NA NA SSO1438 U csx3 Subtype III- csx3 NA NA AF1864 U csx1 Subtype III- csa3, csx1, 1XMX and 2171 COG1517 and MJ1666, NE0113, U csx2, DXTHG, COG4006 PF1127 andTM1812 NE0113 and TIGR02710 csx15 Unknown NA NA TTE2665 TTE2665 csf1 Type U csf1 NA NA AFE_1038 csf2 Type U csf2 NA (RAMP) AFE_1039 csf3 Type U csf3 NA (RAMP) AFE_1040 csf4 Type U csf4 NA NA AFE_1037

IV. Functional Analysis of Candidate Molecules

Candidate Cas9 molecules, candidate gRNA molecules, candidate Cas9 molecule/gRNA molecule complexes, can be evaluated by art-known methods or as described herein. For example, exemplary methods for evaluating the endonuclease activity of Cas9 molecule are described, e.g., in Jinek et al., SCIENCE 2012, 337(6096):816-821.

Binding and Cleavage Assay: Testing the Endonuclease Activity of Cas9 Molecule

The ability of a Cas9 molecule/gRNA molecule complex to bind to and cleave a target nucleic acid can be evaluated in a plasmid cleavage assay. In this assay, synthetic or in vitro-transcribed gRNA molecule is pre-annealed prior to the reaction by heating to 95° C. and slowly cooling down to room temperature. Native or restriction digest-linearized plasmid DNA (300 ng (˜8 nM)) is incubated for 60 min at 37° C. with purified Cas9 protein molecule (50-500 nM) and gRNA (50-500 nM, 1:1) in a Cas9 plasmid cleavage buffer (20 mM HEPES pH 7.5, 150 mM KCl, 0.5 mM DTT, 0.1 mM EDTA) with or without 10 mM MgCl₂. The reactions are stopped with 5×DNA loading buffer (30% glycerol, 1.2% SDS, 250 mM EDTA), resolved by a 0.8 or 1% agarose gel electrophoresis and visualized by ethidium bromide staining. The resulting cleavage products indicate whether the Cas9 molecule cleaves both DNA strands, or only one of the two strands. For example, linear DNA products indicate the cleavage of both DNA strands. Nicked open circular products indicate that only one of the two strands is cleaved.

Alternatively, the ability of a Cas9 molecule/gRNA molecule complex to bind to and cleave a target nucleic acid can be evaluated in an oligonucleotide DNA cleavage assay. In this assay, DNA oligonucleotides (10 pmol) are radiolabeled by incubating with 5 units T4 polynucleotide kinase and ˜3-6 pmol (˜20-40 mCi) [γ-32P]-ATP in 1×T4 polynucleotide kinase reaction buffer at 37° C. for 30 min, in a 50 μL reaction. After heat inactivation (65° C. for 20 min), reactions are purified through a column to remove unincorporated label. Duplex substrates (100 nM) are generated by annealing labeled oligonucleotides with equimolar amounts of unlabeled complementary oligonucleotide at 95° C. for 3 min, followed by slow cooling to room temperature. For cleavage assays, gRNA molecules are annealed by heating to 95° C. for 30 s, followed by slow cooling to room temperature. Cas9 (500 nM final concentration) is pre-incubated with the annealed gRNA molecules (500 nM) in cleavage assay buffer (20 mM HEPES pH 7.5, 100 mM KCl, 5 mM MgCl₂, 1 mM DTT, 5% glycerol) in a total volume of 9 μl. Reactions are initiated by the addition of 1 μl target DNA (10 nM) and incubated for 1 h at 37° C. Reactions are quenched by the addition of 20 μl of loading dye (5 mM EDTA, 0.025% SDS, 5% glycerol in formamide) and heated to 95° C. for 5 min. Cleavage products are resolved on 12% denaturing polyacrylamide gels containing 7 M urea and visualized by phosphorimaging. The resulting cleavage products indicate that whether the complementary strand, the non-complementary strand, or both, are cleaved.

One or both of these assays can be used to evaluate the suitability of a candidate gRNA molecule or candidate Cas9 molecule.

Binding Assay: Testing the Binding of Cas9 Molecule to Target DNA

Exemplary methods for evaluating the binding of Cas9 molecule to target DNA are described, e.g., in Jinek et al., SCIENCE 2012; 337(6096):816-821.

For example, in an electrophoretic mobility shift assay, target DNA duplexes are formed by mixing of each strand (10 nmol) in deionized water, heating to 95° C. for 3 min and slow cooling to room temperature. All DNAs are purified on 8% native gels containing 1×TBE. DNA bands are visualized by UV shadowing, excised, and eluted by soaking gel pieces in DEPC-treated H₂O. Eluted DNA is ethanol precipitated and dissolved in DEPC-treated H₂O. DNA samples are 5′ end labeled with [7-32P]-ATP using T4 polynucleotide kinase for 30 min at 37° C. Polynucleotide kinase is heat denatured at 65° C. for 20 min, and unincorporated radiolabel is removed using a column. Binding assays are performed in buffer containing 20 mM HEPES pH 7.5, 100 mM KCl, 5 mM MgCl₂, 1 mM DTT and 10% glycerol in a total volume of 10 μl. Cas9 protein molecule is programmed with equimolar amounts of pre-annealed gRNA molecule and titrated from 100 pM to 1 μM. Radiolabeled DNA is added to a final concentration of 20 pM. Samples are incubated for 1 h at 37° C. and resolved at 4° C. on an 8% native polyacrylamide gel containing 1×TBE and 5 mM MgCl₂. Gels are dried and DNA visualized by phosphorimaging.

Differential Scanning Flourimetry (DSF)

The thermostability of Cas9-gRNA ribonucleoprotein (RNP) complexes can be measured via DSF. This technique measures the thermostability of a protein, which can increase under favorable conditions such as the addition of a binding RNA molecule, e.g., a gRNA.

The assay is performed using two different protocols, one to test the best stoichiometric ratio of gRNA:Cas9 protein and another to determine the best solution conditions for RNP formation.

To determine the best solution to form RNP complexes, a 2 uM solution of Cas9 in water+10×SYPRO Orange® (Life Techonologies cat #S-6650) and dispensed into a 384 well plate. An equimolar amount of gRNA diluted in solutions with varied pH and salt is then added. After incubating at room temperature for 10′ and brief centrifugation to remove any bubbles, a Bio-Rad CFX384™ Real-Time System C1000 Touch™ Thermal Cycler with the Bio-Rad CFX Manager software is used to run a gradient from 20° C. to 90° C. with a 1° increase in temperature every 10 seconds.

The second assay consists of mixing various concentrations of gRNA with 2 uM Cas9 in optimal buffer from assay 1 above and incubating at RT for 10′ in a 384 well plate. An equal volume of optimal buffer+10×SYPRO Orange® (Life Techonologies cat #S-6650) is added and the plate sealed with Microseal® B adhesive (MSB-1001). Following brief centrifugation to remove any bubbles, a Bio-Rad CFX384™ Real-Time System C1000 Touch™ Thermal Cycler with the Bio-Rad CFX Manager software is used to run a gradient from 20° C. to 90° C. with a 1° increase in temperature every 10 seconds.

V. Genome Editing Approaches

Mutations in the HBB gene may be corrected using one of the approaches discussed herein. In an embodiment, a mutation in the HBB gene is corrected by homology directed repair (HDR) using an exogenously provided template nucleic acid (see Section V.1). In another embodiment, a mutation in the HBB gene is corrected by homology directed repair without using an exogenously provided template nucleic acid (see Section V.1).

Also described herein are methods for targeted knockout of one or both alleles of the BCL11A gene using NHEJ (see Section V.2). In another embodiment, methods are provided for targeted knockdown of the BCL11A gene (see Section V.3).

V.1 HDR Repair and Template Nucleic Acids

As described herein, nuclease-induced homology directed repair (HDR) can be used to alter a target sequence and correct (e.g., repair or edit) a mutation in the genome. While not wishing to be bound by theory, it is believed that alteration of the target sequence occurs by homology-directed repair (HDR) with an exogenously provided donor template or template nucleic acid. For example, the donor template or the template nucleic acid provides for alteration of the target sequence. It is contemplated that a plasmid donor can be used as a template for homologous recombination. It is further contemplated that a single stranded donor template can be used as a template for alteration of the target sequence by alternate methods of homology directed repair (e.g., single strand annealing) between the target sequence and the donor template. Donor template-effected alteration of a target sequence depends on cleavage by a Cas9 molecule. Cleavage by Cas9 can comprise a double strand break or two single strand breaks. As described herein, nuclease-induced homology directed repair (HDR) can be used to alter a target sequence and correct (e.g., repair or edit) a mutation in the genome without the use of an exogenously provided donor template or template nucleic acid. While not wishing to be bound by theory, it is believed that alteration of the target sequence occurs by homology-directed repair (HDR) with endogenous genomic donor sequence. For example, the endogenous genomic donor sequence provides for alteration of the target sequence. It is contemplated that in an embodiment the endogenous genomic donor sequence is located on the same chromosome as the target sequence. It is further contemplated that in another embodiment the endogenous genomic donor sequence is located on a different chromosome from the target sequence. In an embodiment, the endogenous genomic donor sequence comprises one or more nucleotides derived from the HBD gene. Alteration of a target sequence by endogenous genomic donor sequence depends on cleavage by a Cas9 molecule. Cleavage by Cas9 can comprise a double strand break or two single strand breaks.

Mutations that can be corrected by HDR using a template nucleic acid, or using endogenous genomic donor sequence, include point mutations. In an embodiment, a point mutation can be corrected by either a single double-strand break or two single strand breaks. In an embodiment, a point mutation can be corrected by (1) a single double-strand break, (2) two single strand breaks, (3) two double stranded breaks with a break occurring on each side of the target position, (4) one double stranded break and two single strand breaks with the double strand break and two single strand breaks occurring on each side of the target position (5) four single stranded breaks with a pair of single stranded breaks occurring on each side of the target position, or (6) one single stranded break.

In an embodiment where a single-stranded template nucleic acid is used, the target position can be altered by alternative HDR.

Donor template-effected alteration of a target position depends on cleavage by a Cas9 molecule. Cleavage by Cas9 can comprise a nick, a double strand break, or two single strand breaks, e.g., one on each strand of the target nucleic acid. After introduction of the breaks on the target nucleic acid, resection occurs at the break ends resulting in single stranded overhanging DNA regions.

In canonical HDR, a double-stranded donor template is introduced, comprising homologous sequence to the target nucleic acid that will either be directly incorporated into the target nucleic acid or used as a template to correct the sequence of the target nucleic acid. After resection at the break, repair can progress by different pathways, e.g., by the double Holliday junction model (or double strand break repair, DSBR, pathway) or the synthesis-dependent strand annealing (SDSA) pathway. In the double Holliday junction model, strand invasion by the two single stranded overhangs of the target nucleic acid to the homologous sequences in the donor template occurs, resulting in the formation of an intermediate with two Holliday junctions. The junctions migrate as new DNA is synthesized from the ends of the invading strand to fill the gap resulting from the resection. The end of the newly synthesized DNA is ligated to the resected end, and the junctions are resolved, resulting in the correction of the target nucleic acid, e.g., incorporation of the correct sequence of the donor template at the corresponding target position. Crossover with the donor template may occur upon resolution of the junctions. In the SDSA pathway, only one single stranded overhang invades the donor template and new DNA is synthesized from the end of the invading strand to fill the gap resulting from resection. The newly synthesized DNA then anneals to the remaining single stranded overhang, new DNA is synthesized to fill in the gap, and the strands are ligated to produce the corrected DNA duplex.

In alternative HDR, a single strand donor template, e.g., template nucleic acid, is introduced. A nick, single strand break, or double strand break at the target nucleic acid, for altering a desired target position, is mediated by a Cas9 molecule, e.g., described herein, and resection at the break occurs to reveal single stranded overhangs. Incorporation of the sequence of the template nucleic acid to correct or alter the target position of the target nucleic acid typically occurs by the SDSA pathway, as described above.

Methods of promoting HDR pathways, e.g., canonical HDR or alt-HDR, are described herein in Section VI.

Additional details on template nucleic acids are provided in Section IV entitled “Template nucleic acids” in International Application PCT/US2014/057905.

Mutations in the HBB gene that can be corrected (e.g., altered) by HDR with a template nucleic acid or with endogenous genomic donor sequence include, e.g., point mutation at E6, e.g., E6V.

Double Strand Break Mediated Correction

In an embodiment, double strand cleavage is effected by a Cas9 molecule having cleavage activity associated with an HNH-like domain and cleavage activity associated with a RuvC-like domain, e.g., an N-terminal RuvC-like domain, e.g., a wild type Cas9. Such embodiments require only a single gRNA.

Single Strand Break Mediated Correction

In some embodiments, one single strand break, or nick, is effected by a Cas9 molecule having nickase activity, e.g., a Cas9 nickase as described herein. A nicked target nucleic acid can be a substrate for alt-HDR.

In other embodiments, two single strand breaks, or nicks, are effected by a Cas9 molecule having nickase activity, e.g., cleavage activity associated with an HNH-like domain or cleavage activity associated with an N-terminal RuvC-like domain. Such embodiments usually require two gRNAs, one for placement of each single strand break. In an embodiment, the Cas9 molecule having nickase activity cleaves the strand to which the gRNA hybridizes, but not the strand that is complementary to the strand to which the gRNA hybridizes. In an embodiment, the Cas9 molecule having nickase activity does not cleave the strand to which the gRNA hybridizes, but rather cleaves the strand that is complementary to the strand to which the gRNA hybridizes.

In an embodiment, the nickase has HNH activity, e.g., a Cas9 molecule having the RuvC activity inactivated, e.g., a Cas9 molecule having a mutation at D10, e.g., the D10A mutation. D10A inactivates RuvC; therefore, the Cas9 nickase has (only) HNH activity and will cut on the strand to which the gRNA hybridizes (e.g., the complementary strand, which does not have the NGG PAM on it). In other embodiments, a Cas9 molecule having an H840, e.g., an H840A, mutation can be used as a nickase. H840A inactivates HNH; therefore, the Cas9 nickase has (only) RuvC activity and cuts on the non-complementary strand (e.g., the strand that has the NGG PAM and whose sequence is identical to the gRNA). In other embodiments, a Cas9 molecule having an N863 mutation, e.g., the N863A mutation, mutation can be used as a nickase. N863A inactivates HNH therefore the Cas9 nickase has (only) RuvC activity and cuts on the non-complementary strand (the strand that has the NGG PAM and whose sequence is identical to the gRNA).

In an embodiment, in which a nickase and two gRNAs are used to position two single strand nicks, one nick is on the + strand and one nick is on the − strand of the target nucleic acid. The PAMs can be outwardly facing. The gRNAs can be selected such that the gRNAs are separated by, from about 0-50, 0-100, or 0-200 nucleotides. In an embodiment, there is no overlap between the target sequences that are complementary to the targeting domains of the two gRNAs. In an embodiment, the gRNAs do not overlap and are separated by as much as 50, 100, or 200 nucleotides. In an embodiment, the use of two gRNAs can increase specificity, e.g., by decreasing off-target binding (Ran et al., Cell 2013; 154(6):1380-1389).

In an embodiment, a single nick can be used to induce HDR, e.g., alt-HDR. It is contemplated herein that a single nick can be used to increase the ratio of HR to NHEJ at a given cleavage site. In an embodiment, a single strand break is formed in the strand of the target nucleic acid to which the targeting domain of said gRNA is complementary. In another embodiment, a single strand break is formed in the strand of the target nucleic acid other than the strand to which the targeting domain of said gRNA is complementary.

Placement of Double Strand or Single Strand Breaks Relative to the Target Position

The double strand break or single strand break in one of the strands should be sufficiently close to target position such that an alteration is produced in the desired region, e.g., correction of a mutation occurs. In an embodiment, the distance is not more than 50, 100, 200, 300, 350 or 400 nucleotides. While not wishing to be bound by theory, in some embodiments, it is believed that the break should be sufficiently close to target position such that the target position is within the region that is subject to exonuclease-mediated removal during end resection. If the distance between the target position and a break is too great, the mutation or other sequence desired to be altered may not be included in the end resection and, therefore, may not be corrected, as donor sequence, either exogenously provided donor sequence or endogenous genomic donor sequence, in some embodiments is only used to correct sequence within the end resection region.

In an embodiment, the targeting domain is configured such that a cleavage event, e.g., a double strand or single strand break, is positioned within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150 or 200 nucleotides of the region desired to be altered, e.g., a mutation. The break, e.g., a double strand or single strand break, can be positioned upstream or downstream of the region desired to be altered, e.g., a mutation. In some embodiments, a break is positioned within the region desired to be altered, e.g., within a region defined by at least two mutant nucleotides. In some embodiments, a break is positioned immediately adjacent to the region desired to be altered, e.g., immediately upstream or downstream of a mutation. In an embodiment, a single strand break is accompanied by an additional single strand break, positioned by a second gRNA molecule, as discussed below. For example, the targeting domains bind configured such that a cleavage event, e.g., the two single strand breaks, are positioned within 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 150 or 200 nucleotides of a target position. In an embodiment, the first and second gRNA molecules are configured such, that when guiding a Cas9 nickase, a single strand break will be accompanied by an additional single strand break, positioned by a second gRNA, sufficiently close to one another to result in alteration of the desired region. In an embodiment, the first and second gRNA molecules are configured such that a single strand break positioned by said second gRNA is within 10, 20, 30, 40, or 50 nucleotides of the break positioned by said first gRNA molecule, e.g., when the Cas9 is a nickase. In an embodiment, the two gRNA molecules are configured to position cuts at the same position, or within a few nucleotides of one another, on different strands, e.g., essentially mimicking a double strand break.

In an embodiment, in which a gRNA (unimolecular (or chimeric) or modular gRNA) and Cas9 nuclease induce a double strand break for the purpose of inducing HDR-mediated correction, the cleavage site is between 0-200 bp (e.g., 0-175, 0 to 150, 0 to 125, 0 to 100, 0 to 75, 0 to 50, 0 to 25, 25 to 200, 25 to 175, 25 to 150, 25 to 125, 25 to 100, 25 to 75, 25 to 50, 50 to 200, 50 to 175, 50 to 150, 50 to 125, 50 to 100, 50 to 75, 75 to 200, 75 to 175, 75 to 150, 75 to 125, 75 to 100 bp) away from the target position. In an embodiment, the cleavage site is between 0-100 bp (e.g., 0 to 75, 0 to 50, 0 to 25, 25 to 100, 25 to 75, 25 to 50, 50 to 100, 50 to 75 or 75 to 100 bp) away from the target position.

In embodiments, one can promote HDR by using nickases to generate a break with overhangs. While not wishing to be bound by theory, the single stranded nature of the overhangs can enhance the cell's likelihood of repairing the break by HDR as opposed to, e.g., NHEJ. Specifically, in some embodiments, HDR is promoted by selecting a first gRNA that targets a first nickase to a first target sequence, and a second gRNA that targets a second nickase to a second target sequence which is on the opposite DNA strand from the first target sequence and offset from the first nick.

In an embodiment, the targeting domain of a gRNA molecule is configured to position a cleavage event sufficiently far from a preselected nucleotide, e.g., the nucleotide of a coding region, such that the nucleotide is not altered. In an embodiment, the targeting domain of a gRNA molecule is configured to position an intronic cleavage event sufficiently far from an intron/exon border, or naturally occurring splice signal, to avoid alteration of the exonic sequence or unwanted splicing events. The gRNA molecule may be a first, second, third and/or fourth gRNA molecule, as described herein.

Placement of a First Break and a Second Break Relative to Each Other

In an embodiment, a double strand break can be accompanied by an additional double strand break, positioned by a second gRNA molecule, as is discussed below.

In an embodiment, a double strand break can be accompanied by two additional single strand breaks, positioned by a second gRNA molecule and a third gRNA molecule.

In an embodiment, a first and second single strand breaks can be accompanied by two additional single strand breaks positioned by a third gRNA molecule and a fourth gRNA molecule.

When two or more gRNAs are used to position two or more cleavage events, e.g., double strand or single strand breaks, in a target nucleic acid, it is contemplated that the two or more cleavage events may be made by the same or different Cas9 proteins. For example, when two gRNAs are used to position two double stranded breaks, a single Cas9 nuclease may be used to create both double stranded breaks. When two or more gRNAs are used to position two or more single stranded breaks (nicks), a single Cas9 nickase may be used to create the two or more nicks. When two or more gRNAs are used to position at least one double stranded break and at least one single stranded break, two Cas9 proteins may be used, e.g., one Cas9 nuclease and one Cas9 nickase. It is contemplated that when two or more Cas9 proteins are used that the two or more Cas9 proteins may be delivered sequentially to control specificity of a double stranded versus a single stranded break at the desired position in the target nucleic acid.

In some embodiments, the targeting domain of the first gRNA molecule and the targeting domain of the second gRNA molecules are complementary to opposite strands of the target nucleic acid molecule. In some embodiments, the gRNA molecule and the second gRNA molecule are configured such that the PAMs are oriented outward.

In certain embodiments, two gRNA are selected to direct Cas9-mediated cleavage at two positions that are a preselected distance from each other. In embodiments, the two points of cleavage are on opposite strands of the target nucleic acid. In some embodiments, the two cleavage points form a blunt ended break, and in other embodiments, they are offset so that the DNA ends comprise one or two overhangs (e.g., one or more 5′ overhangs and/or one or more 3′ overhangs). In some embodiments, each cleavage event is a nick. In embodiments, the nicks are close enough together that they form a break that is recognized by the double stranded break machinery (as opposed to being recognized by, e.g., the SSBr machinery). In embodiments, the nicks are far enough apart that they create an overhang that is a substrate for HDR, i.e., the placement of the breaks mimics a DNA substrate that has experienced some resection. For instance, in some embodiments the nicks are spaced to create an overhang that is a substrate for processive resection. In some embodiments, the two breaks are spaced within 25-65 nucleotides of each other. The two breaks may be, e.g., about 25, 30, 35, 40, 45, 50, 55, 60 or 65 nucleotides of each other. The two breaks may be, e.g., at least about 25, 30, 35, 40, 45, 50, 55, 60 or 65 nucleotides of each other. The two breaks may be, e.g., at most about 30, 35, 40, 45, 50, 55, 60 or 65 nucleotides of each other. In embodiments, the two breaks are about 25-30, 30-35, 35-40, 40-45, 45-50, 50-55, 55-60, or 60-65 nucleotides of each other.

In some embodiments, the break that mimics a resected break comprises a 3′ overhang (e.g., generated by a DSB and a nick, where the nick leaves a 3′ overhang), a 5′ overhang (e.g., generated by a DSB and a nick, where the nick leaves a 5′ overhang), a 3′ and a 5′ overhang (e.g., generated by three cuts), two 3′ overhangs (e.g., generated by two nicks that are offset from each other), or two 5′ overhangs (e.g., generated by two nicks that are offset from each other).

In an embodiment, in which two gRNAs (independently, unimolecular (or chimeric) or modular gRNA) complexing with Cas9 nickases induce two single strand breaks for the purpose of inducing HDR-mediated correction, the closer nick is between 0-200 bp (e.g., 0-175, 0 to 150, 0 to 125, 0 to 100, 0 to 75, 0 to 50, 0 to 25, 25 to 200, 25 to 175, 25 to 150, 25 to 125, 25 to 100, 25 to 75, 25 to 50, 50 to 200, 50 to 175, 50 to 150, 50 to 125, 50 to 100, 50 to 75, 75 to 200, 75 to 175, 75 to 150, 75 to 125, 75 to 100 bp) away from the target position and the two nicks will ideally be within 25-65 bp of each other (e.g., 25 to 50, 25 to 45, 25 to 40, 25 to 35, 25 to 30, 30 to 55, 30 to 50, 30 to 45, 30 to 40, 30 to 35, 35 to 55, 35 to 50, 35 to 45, 35 to 40, 40 to 55, 40 to 50, 40 to 45 bp, 45 to 50 bp, 50 to 55 bp, 55 to 60 bp, 60 to 65 bp) and no more than 100 bp away from each other (e.g., no more than 90, 80, 70, 60, 50, 40, 30, 20, 10 or 5 bp away from each other). In an embodiment, the cleavage site is between 0-100 bp (e.g., 0 to 75, 0 to 50, 0 to 25, 25 to 100, 25 to 75, 25 to 50, 50 to 100, 50 to 75 or 75 to 100 bp) away from the target position.

In one embodiment, two gRNAs, e.g., independently, unimolecular (or chimeric) or modular gRNA, are configured to position a double-strand break on both sides of a target position. In an alternate embodiment, three gRNAs, e.g., independently, unimolecular (or chimeric) or modular gRNA, are configured to position a double strand break (i.e., one gRNA complexes with a cas9 nuclease) and two single strand breaks or paired single stranded breaks (i.e., two gRNAs complex with Cas9 nickases) on either side of the target position. In another embodiment, four gRNAs, e.g., independently, unimolecular (or chimeric) or modular gRNA, are configured to generate two pairs of single stranded breaks (i.e., two pairs of two gRNAs complex with Cas9 nickases) on either side of the target position. The double strand break(s) or the closer of the two single strand nicks in a pair will ideally be within 0-500 bp of the target position (e.g., no more than 450, 400, 350, 300, 250, 200, 150, 100, 50 or 25 bp from the target position). When nickases are used, the two nicks in a pair are, in embodiments, within 25-65 bp of each other (e.g., between 25 to 55, 25 to 50, 25 to 45, 25 to 40, 25 to 35, 25 to 30, 50 to 55, 45 to 55, 40 to 55, 35 to 55, 30 to 55, 30 to 50, 35 to 50, 40 to 50, 45 to 50, 35 to 45, 40 to 45 bp, 45 to 50 bp, 50 to 55 bp, 55 to 60 bp, or 60 to 65 bp) and no more than 100 bp away from each other (e.g., no more than 90, 80, 70, 60, 50, 40, 30, 20 or 10 bp).

When two gRNAs are used to target Cas9 molecules to breaks, different combinations of Cas9 molecules are envisioned. In some embodiments, a first gRNA is used to target a first Cas9 molecule to a first target position, and a second gRNA is used to target a second Cas9 molecule to a second target position. In some embodiments, the first Cas9 molecule creates a nick on the first strand of the target nucleic acid, and the second Cas9 molecule creates a nick on the opposite strand, resulting in a double stranded break (e.g., a blunt ended cut or a cut with overhangs).

Different combinations of nickases can be chosen to target one single stranded break to one strand and a second single stranded break to the opposite strand. When choosing a combination, one can take into account that there are nickases having one active RuvC-like domain, and nickases having one active HNH domain. In an embodiment, a RuvC-like domain cleaves the non-complementary strand of the target nucleic acid molecule. In an embodiment, an HNH-like domain cleaves a single stranded complementary domain, e.g., a complementary strand of a double stranded nucleic acid molecule. Generally, if both Cas9 molecules have the same active domain (e.g., both have an active RuvC domain or both have an active HNH domain), one will choose two gRNAs that bind to opposite strands of the target. In more detail, in some embodiments, a first gRNA is complementary with a first strand of the target nucleic acid and binds a nickase having an active RuvC-like domain and causes that nickase to cleave the strand that is non-complementary to that first gRNA, i.e., a second strand of the target nucleic acid; and a second gRNA is complementary with a second strand of the target nucleic acid and binds a nickase having an active RuvC-like domain and causes that nickase to cleave the strand that is non-complementary to that second gRNA, i.e., the first strand of the target nucleic acid. Conversely, in some embodiments, a first gRNA is complementary with a first strand of the target nucleic acid and binds a nickase having an active HNH domain and causes that nickase to cleave the strand that is complementary to that first gRNA, i.e., a first strand of the target nucleic acid; and a second gRNA is complementary with a second strand of the target nucleic acid and binds a nickase having an active HNH domain and causes that nickase to cleave the strand that is complementary to that second gRNA, i.e., the second strand of the target nucleic acid. In another arrangement, if one Cas9 molecule has an active RuvC-like domain and the other Cas9 molecule has an active HNH domain, the gRNAs for both Cas9 molecules can be complementary to the same strand of the target nucleic acid, so that the Cas9 molecule with the active RuvC-like domain will cleave the non-complementary strand and the Cas9 molecule with the HNH domain will cleave the complementary strand, resulting in a double stranded break.

Length of the Homology Arms of the Donor Template

The homology arm should extend at least as far as the region in which end resection may occur, e.g., in order to allow the resected single stranded overhang to find a complementary region within the donor template. The overall length could be limited by parameters such as plasmid size or viral packaging limits. In an embodiment, a homology arm does not extend into repeated elements, e.g., Alu repeats or LINE repeats.

Exemplary homology arm lengths include at least 50, 100, 250, 500, 750, 1000, 2000, 3000, 4000, or 5000 nucleotides. In some embodiments, the homology arm length is 50-100, 100-250, 250-500, 500-750, 750-1000, 1000-2000, 2000-3000, 3000-4000, or 4000-5000 nucleotides.

Target position, as used herein, refers to a site on a target nucleic acid (e.g., the chromosome) that is modified by a Cas9 molecule-dependent process. For example, the target position can be a modified Cas9 molecule cleavage of the target nucleic acid and template nucleic acid directed modification, e.g., correction, of the target position. In an embodiment, a target position can be a site between two nucleotides, e.g., adjacent nucleotides, on the target nucleic acid into which one or more nucleotides is added. The target position may comprise one or more nucleotides that are altered, e.g., corrected, by a template nucleic acid. In an embodiment, the target position is within a target sequence (e.g., the sequence to which the gRNA binds). In an embodiment, a target position is upstream or downstream of a target sequence (e.g., the sequence to which the gRNA binds).

A template nucleic acid, as that term is used herein, refers to a nucleic acid sequence which can be used in conjunction with a Cas9 molecule and a gRNA molecule to alter the structure of a target position. In an embodiment, the target nucleic acid is modified to have the some or all of the sequence of the template nucleic acid, typically at or near cleavage site(s). In an embodiment, the template nucleic acid is single stranded. In an alternate embodiment, the template nucleic acid is double stranded. In an embodiment, the template nucleic acid is DNA, e.g., double stranded DNA. In an alternate embodiment, the template nucleic acid is single stranded DNA. In an embodiment, the template nucleic acid is encoded on the same vector backbone, e.g. AAV genome, plasmid DNA, as the Cas9 and gRNA. In an embodiment, the template nucleic acid is excised from a vector backbone in vivo, e.g., it is flanked by gRNA recognition sequences. In an embodiment, the template nucleic acid comprises endogenous genomic sequence

In an embodiment, the template nucleic acid alters the structure of the target position by participating in a homology directed repair event. In an embodiment, the template nucleic acid alters the sequence of the target position. In an embodiment, the template nucleic acid results in the incorporation of a modified, or non-naturally occurring base into the target nucleic acid.

Typically, the template sequence undergoes a breakage mediated or catalyzed recombination with the target sequence. In an embodiment, the template nucleic acid includes sequence that corresponds to a site on the target sequence that is cleaved by an eaCas9 mediated cleavage event. In an embodiment, the template nucleic acid includes sequence that corresponds to both, a first site on the target sequence that is cleaved in a first Cas9 mediated event, and a second site on the target sequence that is cleaved in a second Cas9 mediated event.

In an embodiment, the template nucleic acid can include sequence which results in an alteration in the coding sequence of a translated sequence, e.g., one which results in the substitution of one amino acid for another in a protein product, e.g., transforming a mutant allele into a wild type allele, transforming a wild type allele into a mutant allele, and/or introducing a stop codon, insertion of an amino acid residue, deletion of an amino acid residue, or a nonsense mutation.

In other embodiments, the template nucleic acid can include sequence which results in an alteration in a non-coding sequence, e.g., an alteration in an exon or in a 5′ or 3′ non-translated or non-transcribed region. Such alterations include an alteration in a control element, e.g., a promoter, enhancer, and an alteration in a cis-acting or trans-acting control element.

A template nucleic acid having homology with a target position in the HBB gene can be used to alter the structure of a target sequence. The template sequence can be used to alter an unwanted structure, e.g., an unwanted or mutant nucleotide.

A template nucleic acid typically comprises the following components:

[5′ homology arm]-[replacement sequence]-[3′ homology arm].

The homology arms provide for recombination into the chromosome, thus replacing the undesired element, e.g., a mutation or signature, with the replacement sequence. In an embodiment, the homology arms flank the most distal cleavage sites.

In an embodiment, the 3′ end of the 5′ homology arm is the position next to the 5′ end of the replacement sequence. In an embodiment, the 5′ homology arm can extend at least 10, 20, 30, 40, 50, 100, 200, 300, 400, 500, 600, 700, 800, 900, 1000, 1500, 2000, 3000, 4000, or 5000 nucleotides 5′ from the 5′ end of the replacement sequence.

In an embodiment, the 5′ end of the 3′ homology arm is the position next to the 3′ end of the replacement sequence. In an embodiment, the 3′ homology arm can extend at least 10, 20, 30, 40, 50, 100, 200, 300, 400, 500, 600, 700, 800, 900, 1000, 1500, 2000, 3000, 4000, or 5000 nucleotides 3′ from the 3′ end of the replacement sequence.

In an embodiment, to correct a mutation, the homology arms, e.g., the 5′ and 3′ homology arms, may each comprise about 1000 base pairs (bp) of sequence flanking the most distal gRNAs (e.g., 1000 bp of sequence on either side of the mutation).

It is contemplated herein that one or both homology arms may be shortened to avoid including certain sequence repeat elements, e.g., Alu repeats or LINE elements. For example, a 5′ homology arm may be shortened to avoid a sequence repeat element. In other embodiments, a 3′ homology arm may be shortened to avoid a sequence repeat element. In some embodiments, both the 5′ and the 3′ homology arms may be shortened to avoid including certain sequence repeat elements.

It is contemplated herein that template nucleic acids for correcting a mutation may be designed for use as a single-stranded oligonucleotide, e.g., a single-stranded oligodeoxynucleotide (ssODN). When using a ssODN, 5′ and 3′ homology arms may range up to about 200 base pairs (bp) in length, e.g., at least 25, 50, 75, 100, 125, 150, 175, or 200 bp in length. Longer homology arms are also contemplated for ssODNs as improvements in oligonucleotide synthesis continue to be made. In some embodiments, a longer homology arm is made by a method other than chemical synthesis, e.g., by denaturing a long double stranded nucleic acid and purifying one of the strands, e.g., by affinity for a strand-specific sequence anchored to a solid substrate.

While not wishing to be bound by theory, in some embodiments alt-HDR proceeds more efficiently when the template nucleic acid has extended homology 5′ to the nick (i.e., in the 5′ direction of the nicked strand). Accordingly, in some embodiments, the template nucleic acid has a longer homology arm and a shorter homology arm, wherein the longer homology arm can anneal 5′ of the nick. In some embodiments, the arm that can anneal 5′ to the nick is at least 25, 50, 75, 100, 125, 150, 175, or 200, 300, 400, 500, 600, 700, 800, 900, 1000, 1500, 2000, 3000, 4000, or 5000 nucleotides from the nick or the 5′ or 3′ end of the replacement sequence. In some embodiments, the arm that can anneal 5′ to the nick is at least 10%, 20%, 30%, 40%, or 50% longer than the arm that can anneal 3′ to the nick. In some embodiments, the arm that can anneal 5′ to the nick is at least 2×, 3×, 4×, or 5× longer than the arm that can anneal 3′ to the nick. Depending on whether a ssDNA template can anneal to the intact strand or the nicked strand, the homology arm that anneals 5′ to the nick may be at the 5′ end of the ssDNA template or the 3′ end of the ssDNA template, respectively.

Similarly, in some embodiments, the template nucleic acid has a 5′ homology arm, a replacement sequence, and a 3′ homology arm, such that the template nucleic acid has extended homology to the 5′ of the nick. For example, the 5′ homology arm and 3′ homology arm may be substantially the same length, but the replacement sequence may extend farther 5′ of the nick than 3′ of the nick. In some embodiments, the replacement sequence extends at least 10%, 20%, 30%, 40%, 50%, 2×, 3×, 4×, or 5× further to the 5′ end of the nick than the 3′ end of the nick. While not wishing to be bound by theory, in some embodiments alt-HDR proceeds more efficiently when the template nucleic acid is centered on the nick. Accordingly, in some embodiments, the template nucleic acid has two homology arms that are essentially the same size. For instance, the first homology arm of a template nucleic acid may have a length that is within 10%, 9%, 8%, 7%, 6%, 5%, 4%, 3%, 2%, or 1% of the second homology arm of the template nucleic acid.

Similarly, in some embodiments, the template nucleic acid has a 5′ homology arm, a replacement sequence, and a 3′ homology arm, such that the template nucleic acid extends substantially the same distance on either side of the nick. For example, the homology arms may have different lengths, but the replacement sequence may be selected to compensate for this. For example, the replacement sequence may extend further 5′ from the nick than it does 3′ of the nick, but the homology arm 5′ of the nick is shorter than the homology arm 3′ of the nick, to compensate. The converse is also possible, e.g., that the replacement sequence may extend further 3′ from the nick than it does 5′ of the nick, but the homology arm 3′ of the nick is shorter than the homology arm 5′ of the nick, to compensate.

Exemplary Arrangements of Linear Nucleic Acid Template Systems

In an embodiment, the nucleic acid template system is double stranded. In an embodiment, the nucleic acid template system is single stranded. In an embodiment, the nucleic acid template system comprises a single stranded portion and a double stranded portion. In an embodiment, the template nucleic acid comprises about 50 to 100, e.g., 55 to 95, 60 to 90, 65 to 85, or 70 to 80, base pairs, homology on either side of the nick and/or replacement sequence. In an embodiment, the template nucleic acid comprises about 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, or 100 base pairs homology 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequences.

In an embodiment, the template nucleic acid comprises about 150 to 200, e.g., 155 to 195, 160 to 190, 165 to 185, or 170 to 180, base pairs homology 3′ of the nick and/or replacement sequence. In an embodiment, the template nucleic acid comprises about 150, 155, 160, 165, 170, 175, 180, 185, 190, 195, or 200 base pairs homology 3′ of the nick or replacement sequence. In an embodiment, the template nucleic acid comprises less than about 100, 90, 80, 70, 60, 50, 40, 30, 20, 15, or 10 base pairs homology 5′ of the nick or replacement sequence.

In an embodiment, the template nucleic acid comprises about 150 to 200, e.g., 155 to 195, 160 to 190, 165 to 185, or 170 to 180, base pairs homology 5′ of the nick and/or replacement sequence. In an embodiment, the template nucleic acid comprises about 150, 155, 160, 165, 170, 175, 180, 185, 190, 195, or 200 base pairs homology 5′ of the nick or replacement sequence. In an embodiment, the template nucleic acid comprises less than about 100, 90, 80, 70, 60, 50, 40, 30, 20, 15, or 10 base pairs homology 3′ of the nick or replacement sequence.

Exemplary Template Nucleic Acids

In an embodiment, the template nucleic acid is a single stranded nucleic acid. In another embodiment, the template nucleic acid is a double stranded nucleic acid. In some embodiments, the template nucleic acid comprises a nucleotide sequence, e.g., of one or more nucleotides, that will be added to or will template a change in the target nucleic acid. In other embodiments, the template nucleic acid comprises a nucleotide sequence that may be used to modify the target position. In other embodiments, the template nucleic acid comprises a nucleotide sequence, e.g., of one or more nucleotides, that corresponds to wild type sequence of the target nucleic acid, e.g., of the target position.

The template nucleic acid may comprise a replacement sequence. In some embodiments, the template nucleic acid comprises a 5′ homology arm. In other embodiments, the template nucleic acid comprises a 3′ homology arm.

In embodiments, the template nucleic acid is linear double stranded DNA. The length may be, e.g., about 150-200 base pairs, e.g., about 150, 160, 170, 180, 190, or 200 base pairs. The length may be, e.g., at least 150, 160, 170, 180, 190, or 200 base pairs. In some embodiments, the length is no greater than 150, 160, 170, 180, 190, or 200 base pairs. In some embodiments, a double stranded template nucleic acid has a length of about 160 base pairs, e.g., about 155-165, 150-170, 140-180, 130-190, 120-200, 110-210, 100-220, 90-230, or 80-240 base pairs.

The template nucleic acid can be linear single stranded DNA. In embodiments, the template nucleic acid is (i) linear single stranded DNA that can anneal to the nicked strand of the target nucleic acid, (ii) linear single stranded DNA that can anneal to the intact strand of the target nucleic acid, (iii) linear single stranded DNA that can anneal to the transcribed strand of the target nucleic acid, (iv) linear single stranded DNA that can anneal to the non-transcribed strand of the target nucleic acid, or more than one of the preceding. The length may be, e.g., about 150-200 nucleotides, e.g., about 150, 160, 170, 180, 190, or 200 nucleotides. The length may be, e.g., at least 150, 160, 170, 180, 190, or 200 nucleotides. In some embodiments, the length is no greater than 150, 160, 170, 180, 190, or 200 nucleotides. In some embodiments, a single stranded template nucleic acid has a length of about 160 nucleotides, e.g., about 155-165, 150-170, 140-180, 130-190, 120-200, 110-210, 100-220, 90-230, or 80-240 nucleotides.

In some embodiments, the template nucleic acid is circular double stranded DNA, e.g., a plasmid. In some embodiments, the template nucleic acid comprises about 500 to 1000 base pairs of homology on either side of the replacement sequence and/or the nick. In some embodiments, the template nucleic acid comprises about 300, 400, 500, 600, 700, 800, 900, 1000, 1500, or 2000 base pairs of homology 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequence. In some embodiments, the template nucleic acid comprises at least 300, 400, 500, 600, 700, 800, 900, 1000, 1500, or 2000 base pairs of homology 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequence. In some embodiments, the template nucleic acid comprises no more than 300, 400, 500, 600, 700, 800, 900, 1000, 1500, or 2000 base pairs of homology 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequence.

In some embodiments, the template nucleic acid is an adenovirus vector, e.g., an AAV vector, e.g., a ssDNA molecule of a length and sequence that allows it to be packaged in an AAV capsid. The vector may be, e.g., less than 5 kb and may contain an ITR sequence that promotes packaging into the capsid. The vector may be integration-deficient. In some embodiments, the template nucleic acid comprises about 150 to 1000 nucleotides of homology on either side of the replacement sequence and/or the nick. In some embodiments, the template nucleic acid comprises about 100, 150, 200, 300, 400, 500, 600, 700, 800, 900, 1000, 1500, or 2000 nucleotides 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequence. In some embodiments, the template nucleic acid comprises at least 100, 150, 200, 300, 400, 500, 600, 700, 800, 900, 1000, 1500, or 2000 nucleotides 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequence. In some embodiments, the template nucleic acid comprises at most 100, 150, 200, 300, 400, 500, 600, 700, 800, 900, 1000, 1500, or 2000 nucleotides 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequence.

In some embodiments, the template nucleic acid is a lentiviral vector, e.g., an IDLV (integration deficiency lentivirus). In some embodiments, the template nucleic acid comprises about 500 to 1000 base pairs of homology on either side of the replacement sequence and/or the nick. In some embodiments, the template nucleic acid comprises about 300, 400, 500, 600, 700, 800, 900, 1000, 1500, or 2000 base pairs of homology 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequence. In some embodiments, the template nucleic acid comprises at least 300, 400, 500, 600, 700, 800, 900, 1000, 1500, or 2000 base pairs of homology 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequence. In some embodiments, the template nucleic acid comprises no more than 300, 400, 500, 600, 700, 800, 900, 1000, 1500, or 2000 base pairs of homology 5′ of the nick or replacement sequence, 3′ of the nick or replacement sequence, or both 5′ and 3′ of the nick or replacement sequence.

In many embodiments, the template nucleic acid comprises one or more mutations, e.g., silent mutations, that prevent Cas9 from recognizing and cleaving the template nucleic acid. The template nucleic acid may comprise, e.g., at least 1, 2, 3, 4, 5, 10, 20, or 30 silent mutations relative to the corresponding sequence in the genome of the cell to be altered. In embodiments, the template nucleic acid comprises at most 2, 3, 4, 5, 10, 20, 30, or 50 silent mutations relative to the corresponding sequence in the genome of the cell to be altered.

In an embodiment, the template nucleic acid alters the structure of the target position by participating in a homology directed repair event. In an embodiment, the template nucleic acid alters the sequence of the target position. In an embodiment, the template nucleic acid results in the incorporation of a modified, or non-naturally occurring base into the target nucleic acid.

Typically, the template sequence undergoes a breakage mediated or catalyzed recombination with the target sequence. In an embodiment, the template nucleic acid includes sequence that corresponds to a site on the target sequence that is cleaved by an eaCas9 mediated cleavage event. In an embodiment, the template nucleic acid includes sequence that corresponds to both, a first site on the target sequence that is cleaved in a first Cas9 mediated event, and a second site on the target sequence that is cleaved in a second Cas9 mediated event.

In an embodiment, the template nucleic acid can include sequence which results in an alteration in the coding sequence of a translated sequence, e.g., one which results in the substitution of one amino acid for another in a protein product, e.g., transforming a mutant allele into a wild type allele, transforming a wild type allele into a mutant allele, and/or introducing a stop codon, insertion of an amino acid residue, deletion of an amino acid residue, or a nonsense mutation.

In other embodiments, the template nucleic acid can include sequence which results in an alteration in a non-coding sequence, e.g., an alteration in an exon or in a 5′ or 3′ non-translated or non-transcribed region. Such alterations include an alteration in a control element, e.g., a promoter, enhancer, and an alteration in a cis-acting or trans-acting control element. A template nucleic acid having homology with a target position can be used to alter the structure of a target sequence. The template sequence can be used to alter an unwanted structure, e.g., an unwanted or mutant nucleotide.

Exemplary template nucleic acids (also referred to herein as donor constructs) to correction a mutation, e.g., at E6, e.g., E6V, in the HBB gene, are provided.

Suitable sequence for the 5′ homology arm can be selected from (e.g., includes a portion of) or include the following sequence:

SEQ ID NO: 16257 ATAGGAACTTGAATCAAGGAAATGATTTTAAAACGCAGTATTCTTAGTG GACTAGAGGAAAAAAATAATCTGAGCCAAGTAGAAGACCTTTTCCCCTC CTACCCCTACTTTCTAAGTCACAGAGGCTTTTTGTTCCCCCAGACACTC TTGCAGATTAGTCCAGGCAGAAACAGTTAGATGTCCCCAGTTAACCTCC TATTTGACACCACTGATTACCCCATTGATAGTCACACTTTGGGTTGTAA GTGACTTTTTATTTATTTGTATTTTTGACTGCATTAAGAGGTCTCTAGT TTTTTATCTCTTGTTTCCCAAAACCTAATAAGTAACTAATGCACAGAGC ACATTGATTTGTATTTATTCTATTTTTAGACATAATTTATTAGCATGCA TGAGCAAATTAAGAAAAACAACAACAAATGAATGCATATATATGTATAT GTATGTGTGTATATATACACACATATATATATATATTTTTTCTTTTCTT ACCAGAAGGTTTTAATCCAAATAAGGAGAAGATATGCTTAGAACCGAGG TAGAGTTTTCATCCATTCTGTCCTGTAAGTATTTTGCATATTCTGGAGA CGCAGGAAGAGATCCATCTACATATCCCAAAGCTGAATTATGGTAGACA AAACTCTTCCACTTTTAGTGCATCAACTTCTTATTTGTGTAATAAGAAA ATTGGGAAAACGATCTTCAATATGCTTACCAAGCTGTGATTCCAAATAT TACGTAAATACACTTGCAAAGGAGGATGTTTTTAGTAGCAATTTGTACT GATGGTATGGGGCCAAGAGATATATCTTAGAGGGAGGGCTGAGGGTTTG AAGTCCAACTCCTAAGCCAGTGCCAGAAGAGCCAAGGACAGGTACGGCT GTCATCACTTAGACCTCACCCTGTGGAGCCACACCCTAGGGTTGGCCAA TCTACTCCCAGGAGCAGGGAGGGCAGGAGCCAGGGCTGGGCATAAAAGT CAGGGCAGAGCCATCTATTGCTTACATTTGCTTCTGACACAACTGTGTT CACTAGCAACCTCAAACAGACACCATGGTGCATCTGACTCCTG (5′H arm)

Suitable sequence for the 3′ homology arm can be selected from (e.g., includes a portion of) or include the following sequence:

SEQ ID NO: 16258 GGAGAAGTCTGCCGTTACTGCCCTGTGGGGCAAGGTGAACGTGGATGAA GTTGGTGGTGAGGCCCTGGGCAGGTTGGTATCAAGGTTACAAGACAGGT TTAAGGAGACCAATAGAAACTGGGCATGTGGAGACAGAGAAGACTCTTG GGTTTCTGATAGGCACTGACTCTCTCTGCCTATTGGTCTATTTTCCCAC CCTTAGGCTGCTGGTGGTCTACCCTTGGACCCAGAGGTTCTTTGAGTCC TTTGGGGATCTGTCCACTCCTGATGCTGTTATGGGCAACCCTAAGGTGA AGGCTCATGGCAAGAAAGTGCTCGGTGCCTTTAGTGATGGCCTGGCTCA CCTGGACAACCTCAAGGGCACCTTTGCCACACTGAGTGAGCTGCACTGT GACAAGCTGCACGTGGATCCTGAGAACTTCAGGGTGAGTCTATGGGACG CTTGATGTTTTCTTTCCCCTTCTTTTCTATGGTTAAGTTCATGTCATAG GAAGGGGATAAGTAACAGGGTACAGTTTAGAATGGGAAACAGACGAATG ATTGCATCAGTGTGGAAGTCTCAGGATCGTTTTAGTTTCTTTTATTTGC TGTTCATAACAATTGTTTTCTTTTGTTTAATTCTTGCTTTCTTTTTTTT TCTTCTCCGCAATTTTTACTATTATACTTAATGCCTTAACATTGTGTAT AACAAAAGGAAATATCTCTGAGATACATTAAGTAACTTAAAAAAAAACT TTACACAGTCTGCCTAGTACATTACTATTTGGAATATATGTGTGCTTAT TTGCATATTCATAATCTCCCTACTTTATTTTCTTTTATTTTTAATTGAT ACATAATCATTATACATATTTATGGGTTAAAGTGTAATGTTTTAATATG TGTACACATATTGACCAAATCAGGGTAATTTTGCATTTGTAATTTTAAA AAATGCTTTCTTCTTTTAATATACTTTTTTGTTTATCTTATTTCTAATA CTTTCCCTAATCTCTTTCTTTCAGGGCAATAATGATACAATGTATCATG CCTCTTTGCACCATTCTAAAGAATAACAGTGATAATTTCTGGGTTAAGG CAATAGCAATATCTCTGCATATAAATATTTCTGCATATAAATTGTAACT G (3′H arm)

In an embodiment, the replacement sequence comprises or consists of an adenine (A) residue to correct the amino acid sequence to a glutamic acid (E) residue.

In an embodiment, to correct a mutation, e.g., at E6, e.g., E6V, in the HBB gene, the homology arms, e.g., the 5′ and 3′ homology arms, may each comprise about 1000 base pairs (bp) of sequence flanking the most distal gRNAs (e.g., 1100 bp of sequence on either side of the mutation). The 5′ homology arm is shown as bold sequence, codon 6 is shown as underlined sequence, the inserted base to correct the mutation at E6, e.g., E6V, is shown as boxed sequence, and the 3′ homology arm is shown as no emphasis sequence.

ATAGGAACTTGAATCAAGGAAATGATTTTAAAACGCAGTATTCTTAGTGGACTA GAGGAAAAAAATAATCTGAGCCAAGTAGAAGACCTTTTCCCCTCCTACCCCTAC TTTCTAAGTCACAGAGGCTTTTTGTTCCCCCAGACACTCTTGCAGATTAGTCCA GGCAGAAACAGTTAGATGTCCCCAGTTAACCTCCTATTTGACACCACTGATTAC CCCATTGATAGTCACACTTTGGGTTGTAAGTGACTTTTTATTTATTTGTATTTTT GACTGCATTAAGAGGTCTCTAGTTTTTTATCTCTTGTTTCCCAAAACCTAATAA GTAACTAATGCACAGAGCACATTGATTTGTATTTATTCTATTTTTAGACATAATT TATTAGCATGCATGAGCAAATTAAGAAAAACAACAACAAATGAATGCATATATA TGTATATGTATGTGTGTATATATACACACATATATATATATATTTTTTCTTTTCT TACCAGAAGGTTTTAATCCAAATAAGGAGAAGATATGCTTAGAACCGAGGTAG AGTTTTCATCCATTCTGTCCTGTAAGTATTTTGCATATTCTGGAGACGCAGGAA GAGATCCATCTACATATCCCAAAGCTGAATTATGGTAGACAAAACTCTTCCACT TTTAGTGCATCAACTTCTTATTTGTGTAATAAGAAAATTGGGAAAACGATCTTC AATATGCTTACCAAGCTGTGATTCCAAATATTACGTAAATACACTTGCAAAGGA GGATGTTTTTAGTAGCAATTTGTACTGATGGTATGGGGCCAAGAGATATATCTT AGAGGGAGGGCTGAGGGTTTGAAGTCCAACTCCTAAGCCAGTGCCAGAAGAGC CAAGGACAGGTACGGCTGTCATCACTTAGACCTCACCCTGTGGAGCCACACCC TAGGGTTGGCCAATCTACTCCCAGGAGCAGGGAGGGCAGGAGCCAGGGCTGG GCATAAAAGTCAGGGCAGAGCCATCTATTGCTTACATTTGCTTCTGACACAACT

AGTCTGCCGTTACTGCCCTGTGGGGCAAGGTGAACGTGGATGAAGTTGGTGGTGAG GCCCTGGGCAGGTTGGTATCAAGGTTACAAGACAGGTTTAAGGAGACCAATAGAAA CTGGGCATGTGGAGACAGAGAAGACTCTTGGGTTTCTGATAGGCACTGACTCTCTCT GCCTATTGGTCTATTTTCCCACCCTTAGGCTGCTGGTGGTCTACCCTTGGACCCAGAG GTTCTTTGAGTCCTTTGGGGATCTGTCCACTCCTGATGCTGTTATGGGCAACCCTAAG GTGAAGGCTCATGGCAAGAAAGTGCTCGGTGCCTTTAGTGATGGCCTGGCTCACCTG GACAACCTCAAGGGCACCTTTGCCACACTGAGTGAGCTGCACTGTGACAAGCTGCA CGTGGATCCTGAGAACTTCAGGGTGAGTCTATGGGACGCTTGATGTTTTCTTTCCCCT TCTTTTCTATGGTTAAGTTCATGTCATAGGAAGGGGATAAGTAACAGGGTACAGTTT AGAATGGGAAACAGACGAATGATTGCATCAGTGTGGAAGTCTCAGGATCGTTTTAG TTTCTTTTATTTGCTGTTCATAACAATTGTTTTCTTTTGTTTAATTCTTGCTTTCTTTTT TTTTCTTCTCCGCAATTTTTACTATTATACTTAATGCCTTAACATTGTGTATAACAAA AGGAAATATCTCTGAGATACATTAAGTAACTTAAAAAAAAACTTTACACAGTCTGCC TAGTACATTACTATTTGGAATATATGTGTGCTTATTTGCATATTCATAATCTCCCTAC TTTATTTTCTTTTATTTTTAATTGATACATAATCATTATACATATTTATGGGTTAAAGT GTAATGTTTTAATATGTGTACACATATTGACCAAATCAGGGTAATTTTGCATTTGTAA TTTTAAAAAATGCTTTCTTCTTTTAATATACTTTTTTGTTTATCTTATTTCTAATACTTT CCCTAATCTCTTTCTTTCAGGGCAATAATGATACAATGTATCATGCCTCTTTGCACCA TTCTAAAGAATAACAGTGATAATTTCTGGGTTAAGGCAATAGCAATATCTCTGCATA TAAATATTTCTGCATATAAATTGTAACTG (Template Construct 1; SEQ ID NO: 16259)

As described below in Table 27, shorter homology arms, e.g., 5′ and/or 3′ homology arms may be used.

It is contemplated herein that one or both homology arms may be shortened to avoid including certain sequence repeat elements, e.g., Alu repeats, LINE elements. For example, a 5′ homology arm may be shortened to avoid a sequence repeat element. In another embodiment, a 3′ homology arm may be shortened to avoid a sequence repeat element. In an embodiment, both the 5′ and the 3′ homology arms may be shortened to avoid including certain sequence repeat elements.

It is contemplated herein that template nucleic acids for correcting a mutation may designed for use as a single-stranded oligonucleotide (ssODN). When using a ssODN, 5′ and 3′ homology arms may range up to about 200 base pairs (bp) in length, e.g., at least 25, 50, 75, 100, 125, 150, 175, or 200 bp in length. Longer homology arms are also contemplated for ssODNs as improvements in oligonucleotide synthesis continue to be made.

In an embodiment, an ssODN may be used to correct a mutation, e.g., E6V in the HBB gene. For example, the ssODN may include 50 bp 5′ and 3′ homology arms as shown below. The 5′ homology arm is shown as bold sequence, codon 6 is shown as underlined sequence, the inserted base to correct the E6V mutation is shown as boxed sequence, and the 3′ homology arm is shown as no emphasis sequence.

ACTGTGTTCACTAGCAACCTCAAACAGACACCATGGTGCATCTGACTCCT

GAAGT (Template Construct 2; SEQ ID NO: 16260)

Silent Mutations in Donor Construct

It is contemplated herein that Cas9 could potentially cleave donor constructs either prior to or following homology directed repair (e.g., homologous recombination), resulting in a possible non-homologous-end-joining event and further DNA sequence mutation at the chromosomal locus of interest. Therefore, to avoid cleavage of the donor sequence before and/or after Cas9-mediated homology directed repair, alternate versions of the donor sequence may be used where silent mutations are introduced. These silent mutations may disrupt Cas9 binding and cleavage, but not disrupt the amino acid sequence of the repaired gene. For example, mutations may include those made to a donor sequence to repair the HBB gene, the mutant form of which can cause Sickle Cell Disease. If gRNA HBB-6 with the 20-base target sequence CGUUACUGCCCUGUGGGGCA is used to insert a donor sequence including

(SEQ ID NO: 16297)

TGGATGAAGT, where the italic A is the base being corrected and the bracketed bases are those that match the guide RNA, the donor sequence may be changed to

(SEQ ID NO: 16298)

TGGATGAAGT, where the lowercase a has been changed from a G (lower case g in sequence ID xxx) at that position so that codon 15 still codes for the amino acid Arginine but the PAM sequence AGG has been modified to AGA to reduce or eliminate Cas9 cleavage at that locus.

Table 27 below provides exemplary template nucleic acids. In an embodiment, the template nucleic acid includes the 5′ homology arm and the 3′ homology arm of a row from Table 27. In another embodiment, a 5′ homology arm from the first column can be combined with a 3′ homology arm from Table 27. In each embodiment, a combination of the 5′ and 3′ homology arms include a replacement sequence, e.g., an adenine (A) residue.

TABLE 27 5’ homology arm (the number of 3’ homology arm (the number of nucleotides from SEQ ID NO: 5’H, nucleotides from SEQ ID NO: 3’H, beginning at the 3’ end of SEQ ID Replacement beginning at the 5’ end of SEQ ID NO: 5’H) Sequence = A NO: 3’H) 10 or more 10 or more 20 or more 20 or more 50 or more 50 or more 100 or more 100 or more 150 or more 150 or more 200 or more 200 or more 250 or more 250 or more 300 or more 300 or more 350 or more 350 or more 400 or more 400 or more 450 or more 450 or more 500 or more 500 or more 550 or more 550 or more 600 or more 600 or more 650 or more 650 or more 700 or more 700 or more 750 or more 750 or more 800 or more 800 or more 850 or more 850 or more 900 or more 900 or more 1000 or more 1000 or more 1100 or more 1100 or more 1200 or more 1200 or more 1300 or more 1300 or more 1400 or more 1400 or more 1500 or more 1500 or more 1600 or more 1600 or more 1700 or more 1700 or more 1800 or more 1800 or more 1900 or more 1900 or more 1200 or more 1200 or more At least 50 but not long enough to At least 50 but not long enough to include a repeated element. include a repeated element. At least 100 but not long enough to At least 100 but not long enough to include a repeated element. include a repeated element. At least 150 but not long enough to At least 150 but not long enough to include a repeated element. include a repeated element. 5 to 100 nucleotides 5 to 100 nucleotides 10 to 150 nucleotides 10 to 150 nucleotides 20 to 150 nucleotides 20 to 150 nucleotides Template Construct No. 1 Template Construct No. 2

V.2 NHEJ Approaches for Gene Targeting

As described herein, nuclease-induced non-homologous end-joining (NHEJ) can be used to target gene-specific knockouts. Nuclease-induced NHEJ can also be used to remove (e.g., delete) sequences in a gene of interest.

While not wishing to be bound by theory, it is believed that, in an embodiment, the genomic alterations associated with the methods described herein rely on nuclease-induced NHEJ and the error-prone nature of the NHEJ repair pathway. NHEJ repairs a double-strand break in the DNA by joining together the two ends; however, generally, the original sequence is restored only if two compatible ends, exactly as they were formed by the double-strand break, are perfectly ligated. The DNA ends of the double-strand break are frequently the subject of enzymatic processing, resulting in the addition or removal of nucleotides, at one or both strands, prior to rejoining of the ends. This results in the presence of insertion and/or deletion (indel) mutations in the DNA sequence at the site of the NHEJ repair. Two-thirds of these mutations typically alter the reading frame and, therefore, produce a non-functional protein. Additionally, mutations that maintain the reading frame, but which insert or delete a significant amount of sequence, can destroy functionality of the protein. This is locus dependent as mutations in critical functional domains are likely less tolerable than mutations in non-critical regions of the protein.

The indel mutations generated by NHEJ are unpredictable in nature; however, at a given break site certain indel sequences are favored and are over represented in the population, likely due to small regions of microhomology. The lengths of deletions can vary widely; most commonly in the 1-50 bp range, but they can reach greater than 100-200 bp. Insertions tend to be shorter and often include short duplications of the sequence immediately surrounding the break site. However, it is possible to obtain large insertions, and in these cases, the inserted sequence has often been traced to other regions of the genome or to plasmid DNA present in the cells.

Because NHEJ is a mutagenic process, it can also be used to delete small sequence motifs (e.g., motifs less than or equal to 50 nucleotides in length) as long as the generation of a specific final sequence is not required. If a double-strand break is targeted near to a target sequence, the deletion mutations caused by the NHEJ repair often span, and therefore remove, the unwanted nucleotides. For the deletion of larger DNA segments, introducing two double-strand breaks, one on each side of the sequence, can result in NHEJ between the ends with removal of the entire intervening sequence. In this way, DNA segments as large as several hundred kilobases can be deleted. Both of these approaches can be used to delete specific DNA sequences; however, the error-prone nature of NHEJ may still produce indel mutations at the site of repair.

Both double strand cleaving eaCas9 molecules and single strand, or nickase, eaCas9 molecules can be used in the methods and compositions described herein to generate NHEJ-mediated indels. NHEJ-mediated indels targeted to the gene, e.g., a coding region, e.g., an early coding region of a gene, of interest can be used to knockout (i.e., eliminate expression of) a gene of interest. For example, early coding region of a gene of interest includes sequence immediately following a start codon, within a first exon of the coding sequence, or within 500 bp of the start codon (e.g., less than 500, 450, 400, 350, 300, 250, 200, 150, 100 or 50 bp).

Placement of Double Strand or Single Strand Breaks Relative to the Target Position

In an embodiment, in which a gRNA and Cas9 nuclease generate a double strand break for the purpose of inducing NHEJ-mediated indels, a gRNA, e.g., a unimolecular (or chimeric) or modular gRNA molecule, is configured to position one double-strand break in close proximity to a nucleotide of the target position. In an embodiment, the cleavage site is between 0-30 bp away from the target position (e.g., less than 30, 25, 20, 15, 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1 bp from the target position).

In an embodiment, in which two gRNAs complexing with Cas9 nickases induce two single strand breaks for the purpose of inducing NHEJ-mediated indels, two gRNAs, e.g., independently, unimolecular (or chimeric) or modular gRNA, are configured to position two single-strand breaks to provide for NHEJ repair a nucleotide of the target position. In an embodiment, the gRNAs are configured to position cuts at the same position, or within a few nucleotides of one another, on different strands, essentially mimicking a double strand break. In an embodiment, the closer nick is between 0-30 bp away from the target position (e.g., less than 30, 25, 20, 15, 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1 bp from the target position), and the two nicks are within 25-55 bp of each other (e.g., between 25 to 50, 25 to 45, 25 to 40, 25 to 35, 25 to 30, 50 to 55, 45 to 55, 40 to 55, 35 to 55, 30 to 55, 30 to 50, 35 to 50, 40 to 50, 45 to 50, 35 to 45, or 40 to 45 bp) and no more than 100 bp away from each other (e.g., no more than 90, 80, 70, 60, 50, 40, 30, 20 or 10 bp). In an embodiment, the gRNAs are configured to place a single strand break on either side of a nucleotide of the target position.

Both double strand cleaving eaCas9 molecules and single strand, or nickase, eaCas9 molecules can be used in the methods and compositions described herein to generate breaks both sides of a target position. Double strand or paired single strand breaks may be generated on both sides of a target position to remove the nucleic acid sequence between the two cuts (e.g., the region between the two breaks in deleted). In one embodiment, two gRNAs, e.g., independently, unimolecular (or chimeric) or modular gRNA, are configured to position a double-strand break on both sides of a target position. In an alternate embodiment, three gRNAs, e.g., independently, unimolecular (or chimeric) or modular gRNA, are configured to position a double strand break (i.e., one gRNA complexes with a cas9 nuclease) and two single strand breaks or paired single strand breaks (i.e., two gRNAs complex with Cas9 nickases) on either side of the target position. In another embodiment, four gRNAs, e.g., independently, unimolecular (or chimeric) or modular gRNA, are configured to generate two pairs of single strand breaks (i.e., two pairs of two gRNAs complex with Cas9 nickases) on either side of the target position. The double strand break(s) or the closer of the two single strand nicks in a pair will ideally be within 0-500 bp of the target position (e.g., no more than 450, 400, 350, 300, 250, 200, 150, 100, 50 or 25 bp from the target position). When nickases are used, the two nicks in a pair are within 25-55 bp of each other (e.g., between 25 to 50, 25 to 45, 25 to 40, 25 to 35, 25 to 30, 50 to 55, 45 to 55, 40 to 55, 35 to 55, 30 to 55, 30 to 50, 35 to 50, 40 to 50, 45 to 50, 35 to 45, or 40 to 45 bp) and no more than 100 bp away from each other (e.g., no more than 90, 80, 70, 60, 50, 40, 30, 20 or 10 bp).

V.3 Targeted Knockdown

Unlike CRISPR/Cas-mediated gene knockout, which permanently eliminates expression by mutating the gene at the DNA level, CRISPR/Cas knockdown allows for temporary reduction of gene expression through the use of artificial transcription factors. Mutating key residues in both DNA cleavage domains of the Cas9 protein (e.g. the D10A and H840A mutations) results in the generation of a catalytically inactive Cas9 (eiCas9 which is also known as dead Cas9 or dCas9) molecule. A catalytically inactive Cas9 complexes with a gRNA and localizes to the DNA sequence specified by that gRNA's targeting domain, however, it does not cleave the target DNA. Fusion of the dCas9 to an effector domain, e.g., a transcription repression domain, enables recruitment of the effector to any DNA site specified by the gRNA. Although an enxymatically inactive (eiCas9) Cas9 molecule itself can block transcription when recruited to early regions in the coding sequence, more robust repression can be achieved by fusing a transcriptional repression domain (for example KRAB, SID or ERD) to the Cas9 and recruiting it to the target knockdown position, e.g., within 1000 bp of sequence 3′ of the start codon or within 500 bp of a promoter region 5′ of the start codon of a gene. It is likely that targeting DNAseI hypersensitive sites (DHSs) of the promoter may yield more efficient gene repression or activation because these regions are more likely to be accessible to the Cas9 protein and are also more likely to harbor sites for endogenous transcription factors. Especially for gene repression, it is contemplated herein that blocking the binding site of an endogenous transcription factor would aid in downregulating gene expression. In an embodiment, one or more eiCas9 molecules may be used to block binding of one or more endogenous transcription factors. In another embodiment, an eiCas9 molecule can be fused to a chromatin modifying protein. Altering chromatin status can result in decreased expression of the target gene. One or more eiCas9 molecules fused to one or more chromatin modifying proteins may be used to alter chromatin status.

In an embodiment, a gRNA molecule can be targeted to a known transcription response elements (e.g., promoters, enhancers, etc.), a known upstream activating sequences (UAS), and/or sequences of unknown or known function that are suspected of being able to control expression of the target DNA.

CRISPR/Cas-mediated gene knockdown can be used to reduce expression of an unwanted allele or transcript. Contemplated herein are scenarios wherein permanent destruction of the gene is not ideal. In these scenarios, site-specific repression may be used to temporarily reduce or eliminate expression. It is also contemplated herein that the off-target effects of a Cas-repressor may be less severe than those of a Cas-nuclease as a nuclease can cleave any DNA sequence and cause mutations whereas a Cas-repressor may only have an effect if it targets the promoter region of an actively transcribed gene. However, while nuclease-mediated knockout is permanent, repression may only persist as long as the Cas-repressor is present in the cells. Once the repressor is no longer present, it is likely that endogenous transcription factors and gene regulatory elements would restore expression to its natural state.

V.4 Single-Strand Annealing

Single strand annealing (SSA) is another DNA repair process that repairs a double-strand break between two repeat sequences present in a target nucleic acid. Repeat sequences utilized by the SSA pathway are generally greater than 30 nucleotides in length. Resection at the break ends occurs to reveal repeat sequences on both strands of the target nucleic acid. After resection, single strand overhangs containing the repeat sequences are coated with RPA protein to prevent the repeats sequences from inappropriate annealing, e.g., to themselves. RAD52 binds to and each of the repeat sequences on the overhangs and aligns the sequences to enable the annealing of the complementary repeat sequences. After annealing, the single-strand flaps of the overhangs are cleaved. New DNA synthesis fills in any gaps, and ligation restores the DNA duplex. As a result of the processing, the DNA sequence between the two repeats is deleted. The length of the deletion can depend on many factors including the location of the two repeats utilized, and the pathway or processivity of the resection.

In contrast to HDR pathways, SSA does not require a template nucleic acid to alter or correct a target nucleic acid sequence. Instead, the complementary repeat sequence is utilized.

V. 5 Other DNA Repair Pathways

SSBR (Single Strand Break Repair)

Single-stranded breaks (SSB) in the genome are repaired by the SSBR pathway, which is a distinct mechanism from the DSB repair mechanisms discussed above. The SSBR pathway has four major stages: SSB detection, DNA end processing, DNA gap filling, and DNA ligation. A more detailed explanation is given in Caldecott, Nature Reviews Genetics 9, 619-631 (August 2008), and a summary is given here.

In the first stage, when a SSB forms, PARP1 and/or PARP2 recognize the break and recruit repair machinery. The binding and activity of PARP1 at DNA breaks is transient and it seems to accelerate SSBr by promoting the focal accumulation or stability of SSBr protein complexes at the lesion. Arguably the most important of these SSBr proteins is XRCC1, which functions as a molecular scaffold that interacts with, stabilizes, and stimulates multiple enzymatic components of the SSBr process including the protein responsible for cleaning the DNA 3′ and 5′ ends. For instance, XRCC1 interacts with several proteins (DNA polymerase beta, PNK, and three nucleases, APE1, APTX, and APLF) that promote end processing. APE1 has endonuclease activity. APLF exhibits endonuclease and 3′ to 5′ exonuclease activities. APTX has endonuclease and 3′ to 5′ exonuclease activity.

This end processing is an important stage of SSBR since the 3′- and/or 5′-termini of most, if not all, SSBs are ‘damaged’. End processing generally involves restoring a damaged 3′-end to a hydroxylated state and and/or a damaged 5′ end to a phosphate moiety, so that the ends become ligation-competent. Enzymes that can process damaged 3′ termini include PNKP, APE1, and TDP1. Enzymes that can process damaged 5′ termini include PNKP, DNA polymerase beta, and APTX. LIG3 (DNA ligase III) can also participate in end processing. Once the ends are cleaned, gap filling can occur.

At the DNA gap filling stage, the proteins typically present are PARP1, DNA polymerase beta, XRCC1, FEN1 (flap endonculease 1), DNA polymerase delta/epsilon, PCNA, and LIG1. There are two ways of gap filling, the short patch repair and the long patch repair. Short patch repair involves the insertion of a single nucleotide that is missing. At some SSBs, “gap filling” might continue displacing two or more nucleotides (displacement of up to 12 bases have been reported). FEN1 is an endonuclease that removes the displaced 5′-residues. Multiple DNA polymerases, including Pol β, are involved in the repair of SSBs, with the choice of DNA polymerase influenced by the source and type of SSB.

In the fourth stage, a DNA ligase such as LIG1 (Ligase I) or LIG3 (Ligase III) catalyzes joining of the ends. Short patch repair uses Ligase III and long patch repair uses Ligase I.

Sometimes, SSBR is replication-coupled. This pathway can involve one or more of CtIP, MRN, ERCC1, and FEN1. Additional factors that may promote SSBR include: aPARP, PARP1, PARP2, PARG, XRCC1, DNA polymerase b, DNA polymerase d, DNA polymerase e, PCNA, LIG1, PNK, PNKP, APE1, APTX, APLF, TDP1, LIG3, FEN1, CtIP, MRN, and ERCC1.

MMR (Mismatch Repair)

Cells contain three excision repair pathways: MMR, BER, and NER. The excision repair pathways hace a common feature in that they typically recognize a lesion on one strand of the DNA, then exo/endonucleaseases remove the lesion and leave a 1-30 nucleotide gap that is sub-sequentially filled in by DNA polymerase and finally sealed with ligase. A more complete picture is given in Li, Cell Research (2008) 18:85-98, and a summary is provided here.

Mismatch repair (MMR) operates on mispaired DNA bases.

The MSH2/6 or MSH2/3 complexes both have ATPases activity that plays an important role in mismatch recognition and the initiation of repair. MSH2/6 preferentially recognizes base-base mismatches and identifies mispairs of 1 or 2 nucleotides, while MSH2/3 preferentially recognizes larger ID mispairs.

hMLH1 heterodimerizes with hPMS2 to form hMutL a which possesses an ATPase activity and is important for multiple steps of MMR. It possesses a PCNA/replication factor C (RFC)-dependent endonuclease activity which plays an important role in 3′ nick-directed MMR involving EXO1. (EXO1 is a participant in both HR and MMR.) It regulates termination of mismatch-provoked excision. Ligase I is the relevant ligase for this pathway. Additional factors that may promote MMR include: EXO1, MSH2, MSH3, MSH6, MLH1, PMS2, MLH3, DNA Pol d, RPA, HMGB1, RFC, and DNA ligase I.

Base Excision Repair (BER)

The base excision repair (BER) pathway is active throughout the cell cycle; it is responsible primarily for removing small, non-helix-distorting base lesions from the genome. In contrast, the related Nucleotide Excision Repair pathway (discussed in the next section) repairs bulky helix-distorting lesions. A more detailed explanation is given in Caldecott, Nature Reviews Genetics 9, 619-631 (August 2008), and a summary is given here.

Upon DNA base damage, base excision repair (BER) is initiated and the process can be simplified into five major steps: (a) removal of the damaged DNA base; (b) incision of the subsequent a basic site; (c) clean-up of the DNA ends; (d) insertion of the correct nucleotide into the repair gap; and (e) ligation of the remaining nick in the DNA backbone. These last steps are similar to the SSBR.

In the first step, a damage-specific DNA glycosylase excises the damaged base through cleavage of the N-glycosidic bond linking the base to the sugar phosphate backbone. Then AP endonuclease-1 (APE1) or bifunctional DNA glycosylases with an associated lyase activity incised the phosphodiester backbone to create a DNA single strand break (SSB). The third step of BER involves cleaning-up of the DNA ends. The fourth step in BER is conducted by Pol R that adds a new complementary nucleotide into the repair gap and in the final step XRCC1/Ligase III seals the remaining nick in the DNA backbone. This completes the short-patch BER pathway in which the majority (˜80%) of damaged DNA bases are repaired. However, if the 5′-ends in step 3 are resistant to end processing activity, following one nucleotide insertion by Pol β there is then a polymerase switch to the replicative DNA polymerases, Pol 6/c, which then add ˜2-8 more nucleotides into the DNA repair gap. This creates a 5′-flap structure, which is recognized and excised by flap endonuclease-1 (FEN-1) in association with the processivity factor proliferating cell nuclear antigen (PCNA). DNA ligase I then seals the remaining nick in the DNA backbone and completes long-patch BER. Additional factors that may promote the BER pathway include: DNA glycosylase, APE 1, Polb, Pold, Pole, XRCC1, Ligase III, FEN-1, PCNA, RECQL4, WRN, MYH, PNKP, and APTX.

Nucleotide Excision Repair (NER)

Nucleotide excision repair (NER) is an important excision mechanism that removes bulky helix-distorting lesions from DNA. Additional details about NER are given in Marteijn et al., Nature Reviews Molecular Cell Biology 15, 465-481 (2014), and a summary is given here. NER a broad pathway encompassing two smaller pathways: global genomic NER (GG-NER) and transcription coupled repair NER (TC-NER). GG-NER and TC-NER use different factors for recognizing DNA damage. However, they utilize the same machinery for lesion incision, repair, and ligation.

Once damage is recognized, the cell removes a short single-stranded DNA segment that contains the lesion. Endonucleases XPF/ERCC1 and XPG (encoded by ERCC5) remove the lesion by cutting the damaged strand on either side of the lesion, resulting in a single-strand gap of 22-30 nucleotides. Next, the cell performs DNA gap filling synthesis and ligation. Involved in this process are: PCNA, RFC, DNA Pol 6, DNA Pol F or DNA Pol x, and DNA ligase I or XRCC1/Ligase III. Replicating cells tend to use DNA pol F and DNA ligase I, while non-replicating cells tend to use DNA Pol 6, DNA Pol K, and the XRCC1/Ligase III complex to perform the ligation step.

NER can involve the following factors: XPA-G, POLH, XPF, ERCC1, XPA-G, and LIG1. Transcription-coupled NER (TC-NER) can involve the following factors: CSA, CSB, XPB, XPD, XPG, ERCC1, and TTDA. Additional factors that may promote the NER repair pathway include XPA-G, POLH, XPF, ERCC1, XPA-G, LIG1, CSA, CSB, XPA, XPB, XPC, XPD, XPF, XPG, TTDA, UVSSA, USP7, CETN2, RAD23B, UV-DDB, CAK subcomplex, RPA, and PCNA.

Interstrand Crosslink (ICL)

A dedicated pathway called the ICL repair pathway repairs interstrand crosslinks. Interstrand crosslinks, or covalent crosslinks between bases in different DNA strand, can occur during replication or transcription. ICL repair involves the coordination of multiple repair processes, in particular, nucleolytic activity, translesion synthesis (TLS), and HDR. Nucleases are recruited to excise the ICL on either side of the crosslinked bases, while TLS and HDR are coordinated to repair the cut strands. ICL repair can involve the following factors: endonucleases, e.g., XPF and RAD51C, endonucleases such as RAD51, translesion polymerases, e.g., DNA polymerase zeta and Rev1), and the Fanconi anemia (FA) proteins, e.g., FancJ.

Other Pathways

Several other DNA repair pathways exist in mammals.

Translesion synthesis (TLS) is a pathway for repairing a single stranded break left after a defective replication event and involves translesion polymerases, e.g., DNA pol□ and Rev1.

Error-free postreplication repair (PRR) is another pathway for repairing a single stranded break left after a defective replication event.

V.6 Examples of gRNAs in Genome Editing Methods

gRNA molecules as described herein can be used with Cas9 molecules that generate a double strand break or a single strand break to alter the sequence of a target nucleic acid, e.g., a target position or target genetic signature. gRNA molecules useful in these methods are described below.

In an embodiment, the gRNA, e.g., a chimeric gRNA, is configured such that it comprises one or more of the following properties;

a) it can position, e.g., when targeting a Cas9 molecule that makes double strand breaks, a double strand break (i) within 50, 100, 150, 200, 250, 300, 350, 400, 450, or 500 nucleotides of a target position, or (ii) sufficiently close that the target position is within the region of end resection;

b) it has a targeting domain of at least 16 nucleotides, e.g., a targeting domain of (i) 16, (ii), 17, (iii) 18, (iv) 19, (v) 20, (vi) 21, (vii) 22, (viii) 23, (ix) 24, (x) 25, or (xi) 26 nucleotides; and

c)

-   -   (i) the proximal and tail domain, when taken together, comprise         at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53         nucleotides, e.g., at least 15, 18, 20, 25, 30, 31, 35, 40, 45,         49, 50, or 53 nucleotides from a naturally occurring S.         pyogenes, S. thermophilus, S. aureus, or N. meningitidis tail         and proximal domain, or a sequence that differs by no more than         1, 2, 3, 4, 5; 6, 7, 8, 9 or 10 nucleotides therefrom;     -   (ii) there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49,         50, or 53 nucleotides 3′ to the last nucleotide of the second         complementarity domain, e.g., at least 15, 18, 20, 25, 30, 31,         35, 40, 45, 49, 50, or 53 nucleotides from the corresponding         sequence of a naturally occurring S. pyogenes, S.         thermophilus, S. aureus, or N. meningitidis gRNA, or a sequence         that differs by no more than 1, 2, 3, 4, 5; 6, 7, 8, 9 or 10         nucleotides therefrom;     -   (iii) there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50,         51, or 54 nucleotides 3′ to the last nucleotide of the second         complementarity domain that is complementary to its         corresponding nucleotide of the first complementarity domain,         e.g., at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54         nucleotides from the corresponding sequence of a naturally         occurring S. pyogenes, S. thermophilus, S. aureus, or N.         meningitidis gRNA, or a sequence that differs by no more than 1,         2, 3, 4, 5; 6, 7, 8, 9 or 10 nucleotides therefrom;     -   (iv) the tail domain is at least 10, 15, 20, 25, 30, 35 or 40         nucleotides in length, e.g., it comprises at least 10, 15, 20,         25, 30, 35 or 40 nucleotides from a naturally occurring S.         pyogenes, S. thermophilus, S. aureus, or N. meningitidis tail         domain, or a sequence that differs by no more than 1, 2, 3, 4,         5; 6, 7, 8, 9 or 10 nucleotides therefrom; or     -   (v) the tail domain comprises 15, 20, 25, 30, 35, 40 nucleotides         or all of the corresponding portions of a naturally occurring         tail domain, e.g., a naturally occurring S. pyogenes, S.         thermophilus, S. aureus, or N. meningitidis tail domain.

In an embodiment, the gRNA is configured such that it comprises properties: a and b(i).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(ii).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(iii).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(iv).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(v).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(vi).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(vii).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(viii).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(ix).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(x).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(xi).

In an embodiment, the gRNA is configured such that it comprises properties: a and c.

In an embodiment, the gRNA is configured such that in comprises properties: a, b, and c.

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(i), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(i), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(ii), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(ii), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(iii), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(iii), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(iv), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(iv), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(v), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(v), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(vi), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(vi), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(vii), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(vii), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(viii), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(viii), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(ix), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(ix), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(x), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(x), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(xi), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(xi), and c(ii).

In an embodiment, the gRNA, e.g., a chimeric gRNA, is configured such that it comprises one or more of the following properties;

a) one or both of the gRNAs can position, e.g., when targeting a Cas9 molecule that makes single strand breaks, a single strand break within (i) 50, 100, 150, 200, 250, 300, 350, 400, 450, or 500 nucleotides of a target position, or (ii) sufficiently close that the target position is within the region of end resection;

b) one or both have a targeting domain of at least 16 nucleotides, e.g., a targeting domain of (i) 16, (ii), 17, (iii) 18, (iv) 19, (v) 20, (vi) 21, (vii) 22, (viii) 23, (ix) 24, (x) 25, or (xi) 26 nucleotides; and

c)

-   -   (i) the proximal and tail domain, when taken together, comprise         at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53         nucleotides, e.g., at least 15, 18, 20, 25, 30, 31, 35, 40, 45,         49, 50, or 53 nucleotides from a naturally occurring S.         pyogenes, S. thermophilus, S. aureus, or N. meningitidis tail         and proximal domain, or a sequence that differs by no more than         1, 2, 3, 4, 5; 6, 7, 8, 9 or 10 nucleotides therefrom;     -   (ii) there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49,         50, or 53 nucleotides 3′ to the last nucleotide of the second         complementarity domain, e.g., at least 15, 18, 20, 25, 30, 31,         35, 40, 45, 49, 50, or 53 nucleotides from the corresponding         sequence of a naturally occurring S. pyogenes, S.         thermophilus, S. aureus, or N. meningitidis gRNA, or a sequence         that differs by no more than 1, 2, 3, 4, 5; 6, 7, 8, 9 or 10         nucleotides therefrom;     -   (iii) there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50,         51, or 54 nucleotides 3′ to the last nucleotide of the second         complementarity domain that is complementary to its         corresponding nucleotide of the first complementarity domain,         e.g., at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54         nucleotides from the corresponding sequence of a naturally         occurring S. pyogenes, S. thermophilus, S. aureus, or N.         meningitidis gRNA, or a sequence that differs by no more than 1,         2, 3, 4, 5; 6, 7, 8, 9 or 10 nucleotides therefrom;     -   (iv) the tail domain is at least 10, 15, 20, 25, 30, 35 or 40         nucleotides in length, e.g., it comprises at least 10, 15, 20,         25, 30, 35 or 40 nucleotides from a naturally occurring S.         pyogenes, S. thermophilus, S. aureus, or N. meningitidis tail         domain, or a sequence that differs by no more than 1, 2, 3, 4,         5; 6, 7, 8, 9 or 10 nucleotides therefrom; or     -   (v) the tail domain comprises 15, 20, 25, 30, 35, 40 nucleotides         or all of the corresponding portions of a naturally occurring         tail domain, e.g., a naturally occurring S. pyogenes, S.         thermophilus, S. aureus, or N. meningitidis tail domain.

In an embodiment, the gRNA is configured such that it comprises properties: a and b(i).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(ii).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(iii).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(iv).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(v).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(vi).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(vii).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(viii).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(ix).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(x).

In an embodiment, the gRNA is configured such that it comprises properties: a and b(xi).

In an embodiment, the gRNA is configured such that it comprises properties: a and c.

In an embodiment, the gRNA is configured such that in comprises properties: a, b, and c.

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(i), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(i), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(ii), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(ii), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(iii), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(iii), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(iv), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(iv), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(v), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(v), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(vi), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(vi), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(vii), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(vii), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(viii), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(viii), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(ix), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(ix), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(x), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(x), and c(ii).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(xi), and c(i).

In an embodiment, the gRNA is configured such that in comprises properties: a(i), b(xi), and c(ii).

In an embodiment, the gRNA is used with a Cas9 nickase molecule having HNH activity, e.g., a Cas9 molecule having the RuvC activity inactivated, e.g., a Cas9 molecule having a mutation at D10, e.g., the D10A mutation.

In an embodiment, the gRNA is used with a Cas9 nickase molecule having RuvC activity, e.g., a Cas9 molecule having the HNH activity inactivated, e.g., a Cas9 molecule having a mutation at 840, e.g., the H840A.

In an embodiment, the gRNAs are used with a Cas9 nickase molecule having RuvC activity, e.g., a Cas9 molecule having the HNH activity inactivated, e.g., a Cas9 molecule having a mutation at N863, e.g., the N863A mutation.

In an embodiment, a pair of gRNAs, e.g., a pair of chimeric gRNAs, comprising a first and a second gRNA, is configured such that they comprises one or more of the following properties;

a) one or both of the gRNAs can position, e.g., when targeting a Cas9 molecule that makes single strand breaks, a single strand break within (i) 50, 100, 150, 200, 250, 300, 350, 400, 450, or 500 nucleotides of a target position, or (ii) sufficiently close that the target position is within the region of end resection;

b) one or both have a targeting domain of at least 16 nucleotides, e.g., a targeting domain of (i) 16, (ii), 17, (iii) 18, (iv) 19, (v) 20, (vi) 21, (vii) 22, (viii) 23, (ix) 24, (x) 25, or (xi) 26 nucleotides;

c) for one or both:

-   -   (i) the proximal and tail domain, when taken together, comprise         at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49, 50, or 53         nucleotides, e.g., at least 15, 18, 20, 25, 30, 31, 35, 40, 45,         49, 50, or 53 nucleotides from a naturally occurring S.         pyogenes, S. thermophilus, S. aureus, or N. meningitidis tail         and proximal domain, or a sequence that differs by no more than         1, 2, 3, 4, 5; 6, 7, 8, 9 or 10 nucleotides therefrom;     -   (ii) there are at least 15, 18, 20, 25, 30, 31, 35, 40, 45, 49,         50, or 53 nucleotides 3′ to the last nucleotide of the second         complementarity domain, e.g., at least 15, 18, 20, 25, 30, 31,         35, 40, 45, 49, 50, or 53 nucleotides from the corresponding         sequence of a naturally occurring S. pyogenes, S.         thermophilus, S. aureus, or N. meningitidis gRNA, or a sequence         that differs by no more than 1, 2, 3, 4, 5; 6, 7, 8, 9 or 10         nucleotides therefrom;     -   (iii) there are at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50,         51, or 54 nucleotides 3′ to the last nucleotide of the second         complementarity domain that is complementary to its         corresponding nucleotide of the first complementarity domain,         e.g., at least 16, 19, 21, 26, 31, 32, 36, 41, 46, 50, 51, or 54         nucleotides from the corresponding sequence of a naturally         occurring S. pyogenes, S. thermophilus, S. aureus, or N.         meningitidis gRNA, or a sequence that differs by no more than 1,         2, 3, 4, 5; 6, 7, 8, 9 or 10 nucleotides therefrom;     -   (iv) the tail domain is at least 10, 15, 20, 25, 30, 35 or 40         nucleotides in length, e.g., it comprises at least 10, 15, 20,         25, 30, 35 or 40 nucleotides from a naturally occurring S.         pyogenes, S. thermophilus, S. aureus, or N. meningitidis tail         domain; or, or a sequence that differs by no more than 1, 2, 3,         4, 5; 6, 7, 8, 9 or 10 nucleotides therefrom; or     -   (v) the tail domain comprises 15, 20, 25, 30, 35, 40 nucleotides         or all of the corresponding portions of a naturally occurring         tail domain, e.g., a naturally occurring S. pyogenes, S.         thermophilus, S. aureus, or N. meningitidis tail domain;

d) the gRNAs are configured such that, when hybridized to target nucleic acid, they are separated by 0-50, 0-100, 0-200, at least 10, at least 20, at least 30 or at least 50 nucleotides;

e) the breaks made by the first gRNA and second gRNA are on different strands; and

f) the PAMs are facing outwards.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(iii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(iv).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(v).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(vi).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(vii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(viii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(ix).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(x).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a and b(xi).

In an embodiment, one or both of the gRNAs configured such that it comprises properties: a and c.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a, b, and c.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(i), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(i), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(i), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(i), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(i), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ii), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ii), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ii), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ii), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ii), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iii), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iii), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iii), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iii), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iii), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iv), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iv), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iv), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iv), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(iv), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(v), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(v), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(v), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(v), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(v), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vi), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vi), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vi), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vi), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vi), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vii), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vii), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vii), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vii), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(vii), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(viii), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(viii), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(viii), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(viii), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(viii), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ix), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ix), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ix), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ix), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(ix), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(x), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(x), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(x), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(x), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(x), c, d, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(xi), and c(i).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(xi), and c(ii).

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(xi), c, and d.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(xi), c, and e.

In an embodiment, one or both of the gRNAs is configured such that it comprises properties: a(i), b(xi), c, d, and e.

In an embodiment, the gRNAs are used with a Cas9 nickase molecule having HNH activity, e.g., a Cas9 molecule having the RuvC activity inactivated, e.g., a Cas9 molecule having a mutation at D10, e.g., the D10A mutation.

In an embodiment, the gRNAs are used with a Cas9 nickase molecule having RuvC activity, e.g., a Cas9 molecule having the HNH activity inactivated, e.g., a Cas9 molecule having a mutation at H840, e.g., the H840A mutation.

In an embodiment, the gRNAs are used with a Cas9 nickase molecule having RuvC activity, e.g., a Cas9 molecule having the HNH activity inactivated, e.g., a Cas9 molecule having a mutation at N863, e.g., the N863A mutation.

VI. Target Cells

Cas9 molecules and gRNA molecules, e.g., a Cas9 molecule/gRNA molecule complex, can be used to manipulate a cell, e.g., to edit a target nucleic acid, in a wide variety of cells.

In an embodiment, a cell is manipulated by editing (e.g., inducing a mutation in) the HBB and/or BCL11A target genes, e.g., as described herein. In an embodiment, the expression of the HBB and/or BCL11A target genes is modulated, e.g., in vivo. In another embodiment, the expression of the HBB and/or BCL11A target genes is modulated, e.g., ex vivo.

The Cas9 and gRNA molecules described herein can be delivered to a target cell. In an embodiment, the target cell is a circulating blood cell, e.g., a reticulocyte, a myeloid progenitor cell, or a hematopoietic stem cell. In an embodiment, the target cell is a bone marrow cell (e.g., a myeloid progenitor cell, an erythroid progenitor cell, a hematopoietic stem cell, or a mesenchymal stem cell). In an embodiment, the target cell is a myeloid progenitor cell (e.g. a common myeloid progenitor (CMP) cell). In an embodiment, the target cell is an erythroid progenitor cell (e.g. a megakaryocyte erythroid progenitor (MEP) cell). In an embodiment, the target cell is a hematopoietic stem cell (e.g. a long term hematopoietic stem cell (LT-HSC), a short term hematopoietic stem cell (ST-HSC), a multipotent progenitor (MPP) cell, a lineage restricted progenitor (LRP) cell).

In an embodiment, the target cell is manipulated ex vivo by editing (e.g., inducing a mutation in) the HBB and/or BCL11A target genes and/or modulating the expression of the HBB and/or BCL11A target genes, and administered to the subject. Sources of target cells for ex vivo manipulation may include, by way of example, the subject's blood, the subject's cord blood, or the subject's bone marrow. Sources of target cells for ex vivo manipulation may also include, by way of example, heterologous donor blood, cord blood, or bone marrow.

In an embodiment, a myeloid progenitor cell is removed from the subject, manipulated ex vivo as described above, and the myeloid progenitor cell is returned to the subject. In an embodiment, an erythroid progenitor cell is removed from the subject, manipulated ex vivo as described above, and the erythroid progenitor cell is returned to the subject. In an embodiment, a hematopoietic stem cell is removed from the subject, manipulated ex vivo as described above, and the hematopoietic stem cell is returned to the subject. In an embodiment, a CD34+ hematopoietic stem cell is removed from the subject, manipulated ex vivo as described above, and the CD34+ hematopoietic stem cell is returned to the subject.

A suitable cell can also include a stem cell such as, by way of example, an embryonic stem cell, an induced pluripotent stem cell, a hematopoietic stem cell, a neuronal stem cell and a mesenchymal stem cell. In an embodiment, the cell is an induced pluripotent stem (iPS) cell or a cell derived from an iPS cell, e.g., an iPS cell generated from the subject, modified to induce a mutation and differentiated into a clinically relevant cell such as a myeloid progenitor cell, an erythroid progenitor cell or a hematopoietic stem cell. In an embodiment, AAV is used to transduce the target cells, e.g., the target cells described herein.

Cells produced by the methods described herein may be used immediately. Alternatively, the cells may be frozen (e.g., in liquid nitrogen) and stored for later use. The cells will usually be frozen in 10% dimehtylsulfoxide (DMSO), 50% serum, 40% buffered medium, or some other such solution as is commonly used in the art to preserve cells at such freezing temperature and thawed in such a manner as commonly known in the art for thawing frozen cultured cells.

VII. Delivery, Formulations and Routes of Administration

The components, e.g., a Cas9 molecule and gRNA molecule (e.g., a Cas9 molecule/gRNA molecule complex), and a donor template nucleic acid, can be delivered or formulated in a variety of forms, see, e.g., Tables 34-35. In an embodiment, one Cas9 molecule and two or more (e.g., 2, 3, 4, or more) different gRNA molecules are delivered, e.g., by an AAV vector. In an embodiment, the sequence encoding the Cas9 molecule and the sequence(s) encoding the two or more (e.g., 2, 3, 4, or more) different gRNA molecules are present on the same nucleic acid molecule, e.g., an AAV vector. When a Cas9 or gRNA component is encoded as DNA for delivery, the DNA will typically but not necessarily include a control region, e.g., comprising a promoter, to effect expression. Useful promoters for Cas9 molecule sequences include CMV, EFS, EF-1a, MSCV, PGK, CAG promoters. In an embodiment, the promoter is a constitutive promoter. In another embodiment, the promoter is a tissue specific promoter. Useful promoters for gRNAs include H1, 7SK, tRNA, and U6 promoters. Promoters with similar or dissimilar strengths can be selected to tune the expression of components. Sequences encoding a Cas9 molecule can comprise a nuclear localization signal (NLS), e.g., an SV40 NLS. In an embodiment, the sequence encoding a Cas9 molecule comprises at least two nuclear localization signals. In an embodiment a promoter for a Cas9 molecule or a gRNA molecule can be, independently, inducible, tissue specific, or cell specific.

Table 34 provides examples of how the components can be formulated, delivered, or administered.

TABLE 34 Elements Donor Cas9 gRNA Template Molecule(s) Molecule(s) Nucleic Acid Comments DNA DNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, and a gRNA are transcribed from DNA. In this embodiment, they are encoded on separate molecules. In this embodiment, the donor template is provided as a separate DNA molecule. DNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, and a gRNA are transcribed from DNA. In this embodiment, they are encoded on separate molecules. In this embodiment, the donor template is provided on the same DNA molecule that encodes the gRNA. DNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, and a gRNA are transcribed from DNA, here from a single molecule. In this embodiment, the donor template is provided as a separate DNA molecule. DNA DNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, and a gRNA are transcribed from DNA. In this embodiment, they are encoded on separate molecules. In this embodiment, the donor template is provided on the same DNA molecule that encodes the Cas9. DNA RNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, is transcribed from DNA, and a gRNA is provided as in vitro transcribed or synthesized RNA. In this embodiment, the donor template is provided as a separate DNA molecule. DNA RNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, is transcribed from DNA, and a gRNA is provided as in vitro transcribed or synthesized RNA. In this embodiment, the donor template is provided on the same DNA molecule that encodes the Cas9. mRNA RNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, is translated from in vitro transcribed mRNA, and a gRNA is provided as in vitro transcribed or synthesized RNA. In this embodiment, the donor template is provided as a DNA molecule. mRNA DNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, is translated from in vitro transcribed mRNA, and a gRNA is transcribed from DNA. In this embodiment, the donor template is provided as a separate DNA molecule. mRNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, is translated from in vitro transcribed mRNA, and a gRNA is transcribed from DNA. In this embodiment, the donor template is provided on the same DNA molecule that encodes the gRNA. Protein DNA DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, is provided as a protein, and a gRNA is transcribed from DNA. In this embodiment, the donor template is provided as a separate DNA molecule. Protein DNA In this embodiment, a Cas9 molecule, typically an eaCas9 molecule, is provided as a protein, and a gRNA is transcribed from DNA. In this embodiment, the donor template is provided on the same DNA molecule that encodes the gRNA. Protein RNA DNA In this embodiment, an eaCas9 molecule is provided as a protein, and a gRNA is provided as transcribed or synthesized RNA. In this embodiment, the donor template is provided as a DNA molecule.

Table 35 summarizes various delivery methods for the components of a Cas system, e.g., the Cas9 molecule component and the gRNA molecule component, as described herein.

TABLE 35 Delivery Duration into Non- of Genome Type of Dividing Expres- Inte- Molecule Delivery Vector/Mode Cells sion gration Delivered Physical (eg, YES Transient NO Nucleic electroporation, Acids particle gun, Calcium and Phosphate transfection) Proteins Viral Retrovirus NO Stable YES RNA Lentivirus YES Stable YES/NO RNA with modi- fications Adenovirus YES Transient NO DNA Adeno- YES Stable NO DNA Associated Virus (AAV) Vaccinia YES Very NO DNA Virus Transient Herpes YES Stable NO DNA Simplex Virus Non- Cationic YES Transient Depends Nucleic Viral Liposomes on Acids what is and delivered Proteins Polymeric YES Transient Depends Nucleic Nano- on Acids particles what is and delivered Proteins Bio- Attenuated YES Transient NO Nucleic logical Bacteria Acids Non- Engineered YES Transient NO Nucleic Viral Bacteriophages Acids Delivery Mammalian YES Transient NO Nucleic Vehicles Virus-like Acids Particles Biological YES Transient NO Nucleic liposomes: Acids Erythrocyte Ghosts and Exosomes DNA-Based Delivery of a Cas9 Molecule and/or One or More gRNA Molecule and/or a Donor Template

Nucleic acids (e.g., DNA) encoding a Cas9 molecule (e.g., an eaCas9 molecule), a gRNA molecule, a donor template nucleic acid, or any combination (e.g., two or all) thereof, can be administered to subjects or delivered into cells by art-known methods or as described herein. For example, Cas9-encoding and/or gRNA-encoding DNA, as well as donor template nucleic acids, can be delivered, e.g., by vectors (e.g., viral or non-viral vectors), non-vector based methods (e.g., using naked DNA or DNA complexes), or a combination thereof. Donor template molecules can be administered to subjects or delivered into cells by art-known methods or as described herein. For example, donor template molecules can be delivered, e.g., by vectors (e.g., viral or non-viral vectors), non-vector based methods (e.g., using naked DNA or DNA complexes), or a combination thereof.

Nucleic acids (e.g., DNA) encoding Cas9 molecules (e.g., eaCas9 molecules) and/or gRNA molecules can be conjugated to molecules to promote uptake by the target cells (e.g., the target cells describe herein). Donor template molecules can be conjugated to molecules to promote uptake by the target cells (e.g., the target cells describe herein).

In an embodiment, the Cas9- and/or gRNA-encoding DNA is delivered by a vector (e.g., viral vector/virus or plasmid).

A vector can comprise a sequence that encodes a Cas9 molecule and/or a gRNA molecule. A vector can also comprise a sequence encoding a signal peptide (e.g., for nuclear localization, nucleolar localization, mitochondrial localization), fused, e.g., to a Cas9 molecule sequence. For example, ae vector can comprise a nuclear localization sequence (e.g., from SV40) fused to the sequence encoding the Cas9 molecule.

One or more regulatory/control elements, e.g., a promoter, an enhancer, an intron, a polyadenylation signal, a Kozak consensus sequence, internal ribosome entry sites (IRES), a 2A sequence, and splice acceptor or donor can be included in the vectors. In an embodiment, the promoter is recognized by RNA polymerase II (e.g., a CMV promoter). In another embodiment, the promoter is recognized by RNA polymerase III (e.g., a U6 promoter). In an embodiment, the promoter is a regulated promoter (e.g., inducible promoter). In another embodiment, the promoter is a constitutive promoter. In an embodiment, the promoter is a tissue specific promoter. In an embodiment, the promoter is a viral promoter. In another embodiment, the promoter is a non-viral promoter.

In an embodiment, the vector or delivery vehicle is a viral vector (e.g., for generation of recombinant viruses). In an embodiment, the virus is a DNA virus (e.g., dsDNA or ssDNA virus). In another embodiment, the virus is an RNA virus (e.g., an ssRNA virus). Exemplary viral vectors/viruses include, e.g., retroviruses, lentiviruses, adenovirus, adeno-associated virus (AAV), vaccinia viruses, poxviruses, and herpes simplex viruses.

In an embodiment, the virus infects dividing cells. In another embodiment, the virus infects non-dividing cells. In an embodiment, the virus infects both dividing and non-dividing cells. In an embodiment, the virus can integrate into the host genome. In an embodiment, the virus is engineered to have reduced immunity, e.g., in human. In an embodiment, the virus is replication-competent. In another embodiment, the virus is replication-defective, e.g., having one or more coding regions for the genes necessary for additional rounds of virion replication and/or packaging replaced with other genes or deleted. In an embodiment, the virus causes transient expression of the Cas9 molecule and/or the gRNA molecule. In another embodiment, the virus causes long-lasting, e.g., at least 1 week, 2 weeks, 1 month, 2 months, 3 months, 6 months, 9 months, 1 year, 2 years, or permanent expression, of the Cas9 molecule and/or the gRNA molecule. The packaging capacity of the viruses may vary, e.g., from at least about 4 kb to at least about 30 kb, e.g., at least about 5 kb, 10 kb, 15 kb, 20 kb, 25 kb, 30 kb, 35 kb, 40 kb, 45 kb, or 50 kb.

In an embodiment, the viral vector recognizes a specific cell type or tissue. For example, the viral vector can be pseudotyped with a different/alternative viral envelope glycoprotein; engineered with a cell type-specific receptor (e.g., genetic modification(s) of one or more viral envelope glycoproteins to incorporate a targeting ligand such as a peptide ligand, a single chain antibody, or a growth factor); and/or engineered to have a molecular bridge with dual specificities with one end recognizing a viral glycoprotein and the other end recognizing a moiety of the target cell surface (e.g., a ligand-receptor, monoclonal antibody, avidin-biotin and chemical conjugation).

Exemplary viral vectors/viruses include, e.g., retroviruses, lentiviruses, adenovirus, adeno-associated virus (AAV), vaccinia viruses, poxviruses, and herpes simplex viruses.

In an embodiment, the Cas9- and/or gRNA-encoding nucleic acid sequence is delivered by a recombinant retrovirus. In an embodiment, the donor template nucleic acid is delivered by a recombinant retrovirus. In an embodiment, the retrovirus (e.g., Moloney murine leukemia virus) comprises a reverse transcriptase, e.g., that allows integration into the host genome. In an embodiment, the retrovirus is replication-competent. In another embodiment, the retrovirus is replication-defective, e.g., having one of more coding regions for the genes necessary for additional rounds of virion replication and packaging replaced with other genes, or deleted.

In an embodiment, the Cas9- and/or gRNA-encoding nucleic acid sequence is delivered by a recombinant lentivirus. In an embodiment, the donor template nucleic acid is delivered by a recombinant lentivirus. For example, the lentivirus is replication-defective, e.g., does not comprise one or more genes required for viral replication.

In an embodiment, the Cas9- and/or gRNA-encoding DNA is delivered by a recombinant adenovirus. In an embodiment, the donor template nucleic acid is delivered by a recombinant adenovirus. In an embodiment, the adenovirus is engineered to have reduced immunity in human.

In an embodiment, the Cas9- and/or gRNA-encoding DNA is delivered by a recombinant AAV. In an embodiment, the donor template nucleic acid is delivered by a recombinant AAV. In some embodiments, the AAV does not incorporate its genome into that of a host cell, e.g., a target cell as describe herein. In an embodiment, the AAV can incorporate its genome into that of a host cell, e.g., a target cell as described herein. In an embodiment, the AAV is a self-complementary adeno-associated virus (scAAV), e.g., a scAAV that packages both strands which anneal together to form double stranded DNA. AAV serotypes that may be used in the disclosed methods, include AAV1, AAV2, modified AAV2 (e.g., modifications at Y444F, Y500F, Y730F and/or S662V), AAV3, modified AAV3 (e.g., modifications at Y705F, Y731F and/or T492V), AAV4, AAV5, AAV6, modified AAV6 (e.g., modifications at S663V and/or T492V), AAV8, AAV 8.2, AAV9, AAV rh l0, and pseudotyped AAV, such as AAV2/8, AAV2/5 and AAV2/6 can also be used in the disclosed methods.

In an embodiment, an AAV capsid that can be used in the methods described herein is a capsid sequence from serotype AAV1, AAV2, AAV3, AAV4, AAV5, AAV6, AAV7, AAV8, AAV9, AAV.rh8, AAV.rh10, AAV.rh32/33, AAV.rh43, AAV.rh64R1, or AAV7m8.

In an embodiment, the Cas9- and/or gRNA-encoding DNA is delivered in a re-engineered AAV capsid, e.g., with 50% or greater, e.g., 60% or greater, 70% or greater, 80% or greater, 90% or greater, or 95% or greater, sequence homology with a capsid sequence from serotypes AAV1, AAV2, AAV3, AAV4, AAV5, AAV6, AAV7, AAV8, AAV9, AAV.rh8, AAV.rh10, AAV.rh32/33, AAV.rh43, or AAV.rh64R1.

In an embodiment, the Cas9- and/or gRNA-encoding DNA is delivered by a chimeric AAV capsid. In an embodiment, the donor template nucleic acid is delivered by a chimeric AAV capsid. Exemplary chimeric AAV capsids include, but are not limited to, AAV9i1, AAV2i8, AAV-DJ, AAV2G9, AAV2i8G9, or AAV8G9.

In an embodiment, the AAV is a self-complementary adeno-associated virus (scAAV), e.g., a scAAV that packages both strands which anneal together to form double stranded DNA.

In an embodiment, the Cas9- and/or gRNA-encoding DNA is delivered by a hybrid virus, e.g., a hybrid of one or more of the viruses described herein. In an embodiment, the hybrid virus is hybrid of an AAV (e.g., of any AAV serotype), with a Bocavirus, B19 virus, porcine AAV, goose AAV, feline AAV, canine AAV, or MVM.

A Packaging cell is used to form a virus particle that is capable of infecting a target cell. Such a cell includes a 293 cell, which can package adenovirus, and a ψ2 cell or a PA317 cell, which can package retrovirus. A viral vector used in gene therapy is usually generated by a producer cell line that packages a nucleic acid vector into a viral particle. The vector typically contains the minimal viral sequences required for packaging and subsequent integration into a host or target cell (if applicable), with other viral sequences being replaced by an expression cassette encoding the protein to be expressed, eg. Cas9. For example, an AAV vector used in gene therapy typically only possesses inverted terminal repeat (ITR) sequences from the AAV genome which are required for packaging and gene expression in the host or target cell. The missing viral functions can be supplied in trans by the packaging cell line and/or plasmid containing E2A, E4, and VA genes from adenovirus, and plasmid encoding Rep and Cap genes from AAV, as described in “Triple Transfection Protocol.” Henceforth, the viral DNA is packaged in a cell line, which contains a helper plasmid encoding the other AAV genes, namely rep and cap, but lacking ITR sequences. In embodiment, the viral DNA is packaged in a producer cell line, which contains E1A and/or E1B genes from adenovirus. The cell line is also infected with adenovirus as a helper. The helper virus (e.g., adenovirus or HSV) or helper plasmid promotes replication of the AAV vector and expression of AAV genes from the helper plasmid with ITRs. The helper plasmid is not packaged in significant amounts due to a lack of ITR sequences. Contamination with adenovirus can be reduced by, e.g., heat treatment to which adenovirus is more sensitive than AAV.

In an embodiment, the viral vector has the ability of cell type and/or tissue type recognition. For example, the viral vector can be pseudotyped with a different/alternative viral envelope glycoprotein; engineered with a cell type-specific receptor (e.g., geneticmodification of the viral envelope glycoproteins to incorporate targeting ligands such as a peptide ligand, a single chain antibodie, a growth factor); and/or engineered to have a molecular bridge with dual specificities with one end recognizing a viral glycoprotein and the other end recognizing a moiety of the target cell surface (e.g., ligand-receptor, monoclonal antibody, avidin-biotin and chemical conjugation).

In an embodiment, the viral vector achieves cell type specific expression. For example, a tissue-specific promoter can be constructed to restrict expression of the transgene (Cas 9 and gRNA) in only the target cell. The specificity of the vector can also be mediated by microRNA-dependent control of transgene expression. In an embodiment, the viral vector has increased efficiency of fusion of the viral vector and a target cell membrane. For example, a fusion protein such as fusion-competent hemagglutin (HA) can be incorporated to increase viral uptake into cells. In an embodiment, the viral vector has the ability of nuclear localization. For example, aviruse that requires the breakdown of the nuclear envelope (during cell division) and therefore will not infect a non-diving cell can be altered to incorporate a nuclear localization peptide in the matrix protein of the virus thereby enabling the transduction of non-proliferating cells.

In some embodiments, the Cas9- and/or gRNA-encoding DNA is delivered by a non-vector based method (e.g., using naked DNA or DNA complexes). For example, the DNA can be delivered, e.g., by organically modified silica or silicate (Ormosil), electroporation, transient cell compression or squeezing (e.g., as described in Lee, et al., Nano Lett 12: 6322-27), gene gun, sonoporation, magnetofection, lipid-mediated transfection, dendrimers, inorganic nanoparticles, calcium phosphates, or a combination thereof.

In an embodiment, delivery via electroporation comprises mixing the cells with the Cas9- and/or gRNA-encoding DNA in a cartridge, chamber or cuvette and applying one or more electrical impulses of defined duration and amplitude. In an embodiment, delivery via electroporation is performed using a system in which cells are mixed with the Cas9- and/or gRNA-encoding DNA in a vessel connected to a device (eg, a pump) which feeds the mixture into a cartridge, chamber or cuvette wherein one or more electrical impulses of defined duration and amplitude are applied, after which the cells are delivered to a second vessel.

In an embodiment, the Cas9- and/or gRNA-encoding DNA is delivered by a combination of a vector and a non-vector based method. In an embodiment, the donor template nucleic acid is delivered by a combination of a vector and a non-vector based method. For example, a virosome comprises a liposome combined with an inactivated virus (e.g., HIV or influenza virus), which can result in more efficient gene transfer, e.g., in a respiratory epithelial cell than either a viral or a liposomal method alone.

In an embodiment, the delivery vehicle is a non-viral vector. In an embodiment, the non-viral vector is an inorganic nanoparticle. Exemplary inorganic nanoparticles include, e.g., magnetic nanoparticles (e.g., Fe₃MnO₂) or silica. The outer surface of the nanoparticle can be conjugated with a positively charged polymer (e.g., polyethylenimine, polylysine, polyserine) which allows for attachment (e.g., conjugation or entrapment) of payload. In an embodiment, the non-viral vector is an organic nanoparticle (e.g., entrapment of the payload inside the nanoparticle). Exemplary organic nanoparticles include, e.g., SNALP liposomes that contain cationic lipids together with neutral helper lipids which are coated with polyethylene glycol (PEG) and protamine and nucleic acid complex coated with lipid coating.

Exemplary lipids for gene transfer are shown below in Table 36.

TABLE 36 Lipids Used for Gene Transfer Lipid Abbreviation Feature 1,2-Dioleoyl-sn-glycero-3-phosphatidylcholine DOPC Helper 1,2-Dioleoyl-sn-glycero-3- phosphatidylethanolamine DOPE Helper Cholesterol Helper N-[1-(2,3-Dioleyloxy)prophyl]N,N,N- trimethylammonium DOTMA Cationic chloride l,2-Dioleoyloxy-3-trimethylammonium-propane DOTAP Cationic Dioctadecylamidoglycylspermine DOGS Cationic N-(3-Aminopropyl)-N,N-dimethyl- 2,3-bis(dodecyloxy)-1- GAP-DLRIE Cationic propanaminium bromide Cetyltrimethylammonium bromide CTAB Cationic 6-Lauroxyhexyl ornithinate LHON Cationic 1-(2,3-Dioleoyloxypropyl)-2,4,6- trimethylpyridinium 2Oc Cationic 2,3-Dioleyloxy-N-[2(sperminecarboxamido- ethyl]-N,N-dimethyl- DOSPA Cationic 1-propanaminium trifluoroacetate 1,2-Dioleyl-3-trimethylammonium-propane DOPA Cationic N-(2-Hydroxyethyl)-N,N-dimethyl- 2,3-bis(tetradecyloxy)-1- MDRIE Cationic propanaminium bromide Dimyristooxypropyl dimethyl hydroxyethyl ammonium bromide DMRI Cationic 3β-[N-(N’,N’-Dimethylaminoethane)- carbamoyl]cholesterol DC-Chol Cationic Bis-guanidium-tren-cholesterol BGTC Cationic 1,3-Diodeoxy-2-(6-carboxy- spermyl)-propylamide DOSPER Cationic Dimethyloctadecylammonium bromide DDAB Cationic Dioctadecylamidoglicylspermidin DSL Cationic rac-[(2,3-Dioctadecyloxypropyl)(2- hydroxyethyl)]- CLIP-1 Cationic dimethylammonium chloride rac-[2(2,3-Dihexadecyloxypropyl- CLIP-6 Cationic oxymethyloxy)ethyl]trimethylammonium bromide Ethyldimyristoylphosphatidylcholine EDMPC Cationic 1,2-Distearyloxy-N,N-dimethyl- 3-aminopropane DSDMA Cationic 1,2-Dimyristoyl-trimethylammonium propane DMTAP Cationic O,O’-Dimyristyl-N-lysyl aspartate DMKE Cationic 1,2-Distearoyl-sn-glycero-3- ethylphosphocholine DSEPC Cationic N-Palmitoyl D-erythro-sphingosyl carbamoyl-spermine CCS Cationic N-t-Butyl-N0-tetradecyl-3- tetradecylaminopropionamidine diC14-amidine Cationic Octadecenolyoxy[ethyl-2- heptadecenyl-3 hydroxyethyl] DOTIM Cationic imidazolinium chloride N1-Cholesteryloxycarbonyl-3,7- diazanonane-1,9-diamine CDAN Cationic 2-(3-[Bis(3-amino-propyl)- amino]propylamino)-N- RPR209120 Cationic ditetradecylcarbamoylme-ethyl-acetamide

Exemplary polymers for gene transfer are shown below in Table 37.

TABLE 37 Polymers Used for Gene Transfer Polymer Abbreviation Poly(ethylene)glycol PEG Polyethylenimine PEI Dithiobis(succinimidylpropionate) DSP Dimethyl-3,3’-dithiobispropionimidate DTBP Poly(ethylene imine) biscarbamate PEIC Poly(L-lysine) PLL Histidine modified PLL Poly(N-vinylpyrrolidone) PVP Poly(propylenimine) PPI Poly(amidoamine) PAMAM Poly(amido ethylenimine) SS-PAEI Triethylenetetramine TETA Poly(β-aminoester) Poly(4-hydroxy-L-proline ester) PHP Poly(allylamine) Poly (α-[4-aminobutyl]-L-glycolic acid) PAGA Poly(D,L-lactic-co-glycolic acid) PLGA Poly(N-ethyl-4-vinylpyridinium bromide) Poly(phosphazene)s PPZ Poly(phosphoester)s PPE Poly(phosphoramidate)s PPA Poly(N-2-hydroxypropylmethacrylamide) pHPMA Poly (2-(dimethylamino)ethyl methacrylate) pDMAEMA Poly(2-aminoethyl propylene phosphate) PPE-EA Chitosan Galactosylated chitosan N-Dodacylated chitosan Histone Collagen Dextran-spermine D-SPM

In an embodiment, the vehicle has targeting modifications to increase target cell update of nanoparticles and liposomes, e.g., cell specific antigens, monoclonal antibodies, single chain antibodies, aptamers, polymers, sugars, and cell penetrating peptides. In an embodiment, the vehicle uses fusogenic and endosome-destabilizing peptides/polymers. In an embodiment, the vehicle undergoes acid-triggered conformational changes (e.g., to accelerate endosomal escape of the cargo). In an embodiment, a stimuli-cleavable polymer is used, e.g., for release in a cellular compartment. For example, disulfide-based cationic polymers that are cleaved in the reducing cellular environment can be used.

In an embodiment, the delivery vehicle is a biological non-viral delivery vehicle. In an embodiment, the vehicle is an attenuated bacterium (e.g., naturally or artificially engineered to be invasive but attenuated to prevent pathogenesis and expressing the transgene (e.g., Listeria monocytogenes, certain Salmonella strains, Bifidobacterium longum, and modified Escherichia coli), bacteria having nutritional and tissue-specific tropism to target specific tissues, bacteria having modified surface proteins to alter target tissue specificity). In an embodiment, the vehicle is a genetically modified bacteriophage (e.g., engineered phages having large packaging capacity, less immunogenic, containing mammalian plasmid maintenance sequences and having incorporated targeting ligands). In an embodiment, the vehicle is a mammalian virus-like particle. For example, modified viral particles can be generated (e.g., by purification of the “empty” particles followed by ex vivo assembly of the virus with the desired cargo). The vehicle can also be engineered to incorporate targeting ligands to alter target tissue specificity. In an embodiment, the vehicle is a biological liposome. For example, the biological liposome is a phospholipid-based particle derived from human cells (e.g., erythrocyte ghosts, which are red blood cells broken down into spherical structures derived from the subject (e.g., tissue targeting can be achieved by attachment of various tissue or cell-specific ligands), or secretory exosomes—subject (i.e., patient) derived membrane-bound nanovescicle (30-100 nm) of endocytic origin (e.g., can be produced from various cell types and can therefore be taken up by cells without the need of for targeting ligands).

In an embodiment, one or more nucleic acid molecules (e.g., DNA molecules) other than the components of a Cas system, e.g., the Cas9 molecule component and/or the gRNA molecule component described herein, are delivered. In an embodiment, the nucleic acid molecule is delivered at the same time as one or more of the components of the Cas system are delivered. In an embodiment, the nucleic acid molecule is delivered before or after (e.g., less than about 30 minutes, 1 hour, 2 hours, 3 hours, 6 hours, 9 hours, 12 hours, 1 day, 2 days, 3 days, 1 week, 2 weeks, or 4 weeks) one or more of the components of the Cas system are delivered. In an embodiment, the nucleic acid molecule is delivered by a different means than one or more of the components of the Cas system, e.g., the Cas9 molecule component and/or the gRNA molecule component, are delivered. The nucleic acid molecule can be delivered by any of the delivery methods described herein. For example, the nucleic acid molecule can be delivered by a viral vector, e.g., an integration-deficient lentivirus, and the Cas9 molecule component and/or the gRNA molecule component can be delivered by electroporation, e.g., such that the toxicity caused by nucleic acids (e.g., DNAs) can be reduced. In an embodiment, the nucleic acid molecule encodes a therapeutic protein, e.g., a protein described herein. In an embodiment, the nucleic acid molecule encodes an RNA molecule, e.g., an RNA molecule described herein.

Delivery of RNA Encoding a Cas9 Molecule

RNA encoding Cas9 molecules (e.g., eaCas9 molecules or eiCas9 molecules) and/or gRNA molecules, can be delivered into cells, e.g., target cells described herein, by art-known methods or as described herein. For example, Cas9-encoding and/or gRNA-encoding RNA can be delivered, e.g., by microinjection, electroporation, transient cell compression or squeezing (eg, as described in Lee, et al., 2012, Nano Lett 12: 6322-27), lipid-mediated transfection, peptide-mediated delivery, or a combination thereof. Cas9-encoding and/or gRNA-encoding RNA can be conjugated to molecules) promoting uptake by the target cells (e.g., target cells described herein).

In an embodiment, delivery via electroporation comprises mixing the cells with the RNA encoding Cas9 molecules (e.g., eaCas9 molecules, eiCas9 molecules or eiCas9 fusion proteins) and/or gRNA molecules, with or without donor template nucleic acid molecules, in a cartridge, chamber or cuvette and applying one or more electrical impulses of defined duration and amplitude. In an embodiment, delivery via electroporation is performed using a system in which cells are mixed with the RNA encoding Cas9 molecules (e.g., eaCas9 molecules, eiCas9 molecules or eiCas9 fusion proteins) and/or gRNA molecules, with or without donor template nucleic acid molecules in a vessel connected to a device (eg, a pump) which feeds the mixture into a cartridge, chamber or cuvette wherein one or more electrical impulses of defined duration and amplitude are applied, after which the cells are delivered to a second vessel. Cas9-encoding and/or gRNA-encoding RNA can be conjugated to molecules to promote uptake by the target cells (e.g., target cells described herein).

Delivery Cas9 Molecule Protein

Cas9 molecules (e.g., eaCas9 molecules or eiCas9 molecules) can be delivered into cells by art-known methods or as described herein. For example, Cas9 protein molecules can be delivered, e.g., by microinjection, electroporation, transient cell compression or squeezing (eg, as described in Lee, et al [2012] Nano Lett 12: 6322-27), lipid-mediated transfection, peptide-mediated delivery, or a combination thereof. Delivery can be accompanied by DNA encoding a gRNA or by a gRNA. Cas9 protein can be conjugated to molecules promoting uptake by the target cells (e.g., target cells described herein).

In an embodiment, delivery via electroporation comprises mixing the cells with the Cas9 molecules (e.g., eaCas9 molecules, eiCas9 molecules or eiCas9 fusion proteins) and/or gRNA molecules, with or without donor nucleic acid, in a cartridge, chamber or cuvette and applying one or more electrical impulses of defined duration and amplitude. In an embodiment, delivery via electroporation is performed using a system in which cells are mixed with the Cas9 molecules (e.g., eaCas9 molecules, eiCas9 molecules or eiCas9 fusion proteins) and/or gRNA molecules, with or without donor nucleic acid in a vessel connected to a device (eg, a pump) which feeds the mixture into a cartridge, chamber or cuvette wherein one or more electrical impulses of defined duration and amplitude are applied, after which the cells are delivered to a second vessel. Cas9-encoding and/or gRNA-encoding RNA can be conjugated to molecules to promote uptake by the target cells (e.g., target cells described herein).

Route of Administration

Systemic modes of administration include oral and parenteral routes. Parenteral routes include, by way of example, intravenous, intrarterial, intraosseous, intramuscular, intradermal, subcutaneous, intranasal and intraperitoneal routes. Components administered systemically may be modified or formulated to target the components to cells of the blood and bone marrow.

Local modes of administration include, by way of example, intra-bone marrow, intrathecal, and intra-cerebroventricular routes. In an embodiment, significantly smaller amounts of the components (compared with systemic approaches) may exert an effect when administered locally (for example, intra-bone marrow) compared to when administered systemically (for example, intravenously). Local modes of administration can reduce or eliminate the incidence of potentially toxic side effects that may occur when therapeutically effective amounts of a component are administered systemically.

In an embodiment, components described herein are delivered by intra-bone marrow injection. Injections may be made directly into the bone marrow compartment of one or more than one bone. In an embodiment, nanoparticle or viral, e.g., AAV vector, delivery is via intra-bone marrow injection.

Administration may be provided as a periodic bolus or as continuous infusion from an internal reservoir or from an external reservoir (for example, from an intravenous bag). Components may be administered locally, for example, by continuous release from a sustained release drug delivery device

In addition, components may be formulated to permit release over a prolonged period of time. A release system can include a matrix of a biodegradable material or a material which releases the incorporated components by diffusion. The components can be homogeneously or heterogeneously distributed within the release system. A variety of release systems may be useful, however, the choice of the appropriate system will depend upon rate of release required by a particular application. Both non-degradable and degradable release systems can be used. Suitable release systems include polymers and polymeric matrices, non-polymeric matrices, or inorganic and organic excipients and diluents such as, but not limited to, calcium carbonate and sugar (for example, trehalose). Release systems may be natural or synthetic. However, synthetic release systems are preferred because generally they are more reliable, more reproducible and produce more defined release profiles. The release system material can be selected so that components having different molecular weights are released by diffusion through or degradation of the material.

Representative synthetic, biodegradable polymers include, for example: polyamides such as poly(amino acids) and poly(peptides); polyesters such as poly(lactic acid), poly(glycolic acid), poly(lactic-co-glycolic acid), and poly(caprolactone); poly(anhydrides); polyorthoesters; polycarbonates; and chemical derivatives thereof (substitutions, additions of chemical groups, for example, alkyl, alkylene, hydroxylations, oxidations, and other modifications routinely made by those skilled in the art), copolymers and mixtures thereof. Representative synthetic, non-degradable polymers include, for example: polyethers such as poly(ethylene oxide), poly(ethylene glycol), and poly(tetramethylene oxide); vinyl polymers-polyacrylates and polymethacrylates such as methyl, ethyl, other alkyl, hydroxyethyl methacrylate, acrylic and methacrylic acids, and others such as poly(vinyl alcohol), poly(vinyl pyrolidone), and poly(vinyl acetate); poly(urethanes); cellulose and its derivatives such as alkyl, hydroxyalkyl, ethers, esters, nitrocellulose, and various cellulose acetates; polysiloxanes; and any chemical derivatives thereof (substitutions, additions of chemical groups, for example, alkyl, alkylene, hydroxylations, oxidations, and other modifications routinely made by those skilled in the art), copolymers and mixtures thereof.

Poly(lactide-co-glycolide) microsphere can also be used for injection. Typically the microspheres are composed of a polymer of lactic acid and glycolic acid, which are structured to form hollow spheres. The spheres can be approximately 15-30 microns in diameter and can be loaded with components described herein.

Bi-Modal or Differential Delivery of Components

Separate delivery of the components of a Cas system, e.g., the Cas9 molecule component and the gRNA molecule component, and more particularly, delivery of the components by differing modes, can enhance performance, e.g., by improving tissue specificity and safety.

In an embodiment, the Cas9 molecule and the gRNA molecule are delivered by different modes, or as sometimes referred to herein as differential modes. Different or differential modes, as used herein, refer modes of delivery that confer different pharmacodynamic or pharmacokinetic properties on the subject component molecule, e.g., a Cas9 molecule, gRNA molecule, or template nucleic acid. For example, the modes of delivery can result in different tissue distribution, different half-life, or different temporal distribution, e.g., in a selected compartment, tissue, or organ.

Some modes of delivery, e.g., delivery by a nucleic acid vector that persists in a cell, or in progeny of a cell, e.g., by autonomous replication or insertion into cellular nucleic acid, result in more persistent expression of and presence of a component. Examples include viral, e.g., adeno-associated virus or lentivirus, delivery.

By way of example, the components, e.g., a Cas9 molecule and a gRNA molecule, can be delivered by modes that differ in terms of resulting half-life or persistent of the delivered component the body, or in a particular compartment, tissue or organ. In an embodiment, a gRNA molecule can be delivered by such modes. The Cas9 molecule component can be delivered by a mode which results in less persistence or less exposure to the body or a particular compartment or tissue or organ.

More generally, in an embodiment, a first mode of delivery is used to deliver a first component and a second mode of delivery is used to deliver a second component. The first mode of delivery confers a first pharmacodynamic or pharmacokinetic property. The first pharmacodynamic property can be, e.g., distribution, persistence, or exposure, of the component, or of a nucleic acid that encodes the component, in the body, a compartment, tissue or organ. The second mode of delivery confers a second pharmacodynamic or pharmacokinetic property. The second pharmacodynamic property can be, e.g., distribution, persistence, or exposure, of the component, or of a nucleic acid that encodes the component, in the body, a compartment, tissue or organ.

In an embodiment, the first pharmacodynamic or pharmacokinetic property, e.g., distribution, persistence or exposure, is more limited than the second pharmacodynamic or pharmacokinetic property.

In an embodiment, the first mode of delivery is selected to optimize, e.g., minimize, a pharmacodynamic or pharmacokinetic property, e.g., distribution, persistence or exposure.

In an embodiment, the second mode of delivery is selected to optimize, e.g., maximize, a pharmacodynamic or pharmcokinetic property, e.g., distribution, persistence or exposure.

In an embodiment, the first mode of delivery comprises the use of a relatively persistent element, e.g., a nucleic acid, e.g., a plasmid or viral vector, e.g., an AAV or lentivirus. As such vectors are relatively persistent product transcribed from them would be relatively persistent.

In an embodiment, the second mode of delivery comprises a relatively transient element, e.g., an RNA or protein.

In an embodiment, the first component comprises gRNA, and the delivery mode is relatively persistent, e.g., the gRNA is transcribed from a plasmid or viral vector, e.g., an AAV or lentivirus. Transcription of these genes would be of little physiological consequence because the genes do not encode for a protein product, and the gRNAs are incapable of acting in isolation. The second component, a Cas9 molecule, is delivered in a transient manner, for example as mRNA or as protein, ensuring that the full Cas9 molecule/gRNA molecule complex is only present and active for a short period of time.

Furthermore, the components can be delivered in different molecular form or with different delivery vectors that complement one another to enhance safety and tissue specificity.

Use of differential delivery modes can enhance performance, safety and efficacy. E.g., the likelihood of an eventual off-target modification can be reduced. Delivery of immunogenic components, e.g., Cas9 molecules, by less persistent modes can reduce immunogenicity, as peptides from the bacterially-derived Cas enzyme are displayed on the surface of the cell by MHC molecules. A two-part delivery system can alleviate these drawbacks.

Differential delivery modes can be used to deliver components to different, but overlapping target regions. The formation active complex is minimized outside the overlap of the target regions. Thus, in an embodiment, a first component, e.g., a gRNA molecule is delivered by a first delivery mode that results in a first spatial, e.g., tissue, distribution. A second component, e.g., a Cas9 molecule is delivered by a second delivery mode that results in a second spatial, e.g., tissue, distribution. In an embodiment, the first mode comprises a first element selected from a liposome, nanoparticle, e.g., polymeric nanoparticle, and a nucleic acid, e.g., viral vector. The second mode comprises a second element selected from the group. In an embodiment, the first mode of delivery comprises a first targeting element, e.g., a cell specific receptor or an antibody, and the second mode of delivery does not include that element. In embodiment, the second mode of delivery comprises a second targeting element, e.g., a second cell specific receptor or second antibody.

When the Cas9 molecule is delivered in a virus delivery vector, a liposome, or polymeric nanoparticle, there is the potential for delivery to and therapeutic activity in multiple tissues, when it may be desirable to only target a single tissue. A two-part delivery system can resolve this challenge and enhance tissue specificity. If the gRNA molecule and the Cas9 molecule are packaged in separated delivery vehicles with distinct but overlapping tissue tropism, the fully functional complex is only be formed in the tissue that is targeted by both vectors.

Ex Vivo Delivery

In an embodiment, components described in Table 34 are introduced into cells which are then introduced into the subject, e.g., cells are removed from a subject, manipulated ex vivo and then introduced into the subject. Methods of introducing the components can include, e.g., any of the delivery methods described in Table 35.

VIII. Modified Nucleosides, Nucleotides, and Nucleic Acids

Modified nucleosides and modified nucleotides can be present in nucleic acids, e.g., particularly gRNA, but also other forms of RNA, e.g., mRNA, RNAi, or siRNA. As described herein, “nucleoside” is defined as a compound containing a five-carbon sugar molecule (a pentose or ribose) or derivative thereof, and an organic base, purine or pyrimidine, or a derivative thereof. As described herein, “nucleotide” is defined as a nucleoside further comprising a phosphate group.

Modified nucleosides and nucleotides can include one or more of:

(i) alteration, e.g., replacement, of one or both of the non-linking phosphate oxygens and/or of one or more of the linking phosphate oxygens in the phosphodiester backbone linkage;

(ii) alteration, e.g., replacement, of a constituent of the ribose sugar, e.g., of the 2′ hydroxyl on the ribose sugar;

(iii) wholesale replacement of the phosphate moiety with “dephospho” linkers;

(iv) modification or replacement of a naturally occurring nucleobase;

(v) replacement or modification of the ribose-phosphate backbone;

(vi) modification of the 3′ end or 5′ end of the oligonucleotide, e.g., removal, modification or replacement of a terminal phosphate group or conjugation of a moiety; and

(vii) modification of the sugar.

The modifications listed above can be combined to provide modified nucleosides and nucleotides that can have two, three, four, or more modifications. For example, a modified nucleoside or nucleotide can have a modified sugar and a modified nucleobase. In an embodiment, every base of a gRNA is modified, e.g., all bases have a modified phosphate group, e.g., all are phosphorothioate groups. In an embodiment, all, or substantially all, of the phosphate groups of a unimolecular or modular gRNA molecule are replaced with phosphorothioate groups.

In an embodiment, modified nucleotides, e.g., nucleotides having modifications as described herein, can be incorporated into a nucleic acid, e.g., a “modified nucleic acid.” In an embodiment, the modified nucleic acids comprise one, two, three or more modified nucleotides. In an embodiment, at least 5% (e.g., at least about 5%, at least about 10%, at least about 15%, at least about 20%, at least about 25%, at least about 30%, at least about 35%, at least about 40%, at least about 45%, at least about 50%, at least about 55%, at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 90%, at least about 95%, or about 100%) of the positions in a modified nucleic acid are a modified nucleotides.

Unmodified nucleic acids can be prone to degradation by, e.g., cellular nucleases. For example, nucleases can hydrolyze nucleic acid phosphodiester bonds. Accordingly, in one aspect the modified nucleic acids described herein can contain one or more modified nucleosides or nucleotides, e.g., to introduce stability toward nucleases.

In an embodiment, the modified nucleosides, modified nucleotides, and modified nucleic acids described herein can exhibit a reduced innate immune response when introduced into a population of cells, both in vivo and ex vivo. The term “innate immune response” includes a cellular response to exogenous nucleic acids, including single stranded nucleic acids, generally of viral or bacterial origin, which involves the induction of cytokine expression and release, particularly the interferons, and cell death. In an embodiment, the modified nucleosides, modified nucleotides, and modified nucleic acids described herein can disrupt binding of a major groove interacting partner with the nucleic acid. In an embodiment, the modified nucleosides, modified nucleotides, and modified nucleic acids described herein can exhibit a reduced innate immune response when introduced into a population of cells, both in vivo and ex vivo, and also disrupt binding of a major groove interacting partner with the nucleic acid.

Definitions of Chemical Groups

As used herein, “alkyl” is meant to refer to a saturated hydrocarbon group which is straight-chained or branched. Example alkyl groups include methyl (Me), ethyl (Et), propyl (e.g., n-propyl and isopropyl), butyl (e.g., n-butyl, isobutyl, t-butyl), pentyl (e.g., n-pentyl, isopentyl, neopentyl), and the like. An alkyl group can contain from 1 to about 20, from 2 to about 20, from 1 to about 12, from 1 to about 8, from 1 to about 6, from 1 to about 4, or from 1 to about 3 carbon atoms.

As used herein, “aryl” refers to monocyclic or polycyclic (e.g., having 2, 3 or 4 fused rings) aromatic hydrocarbons such as, for example, phenyl, naphthyl, anthracenyl, phenanthrenyl, indanyl, indenyl, and the like. In an embodiment, aryl groups have from 6 to about 20 carbon atoms.

As used herein, “alkenyl” refers to an aliphatic group containing at least one double bond.

As used herein, “alkynyl” refers to a straight or branched hydrocarbon chain containing 2-12 carbon atoms and characterized in having one or more triple bonds. Examples of alkynyl groups include, but are not limited to, ethynyl, propargyl, and 3-hexynyl.

As used herein, “arylalkyl” or “aralkyl” refers to an alkyl moiety in which an alkyl hydrogen atom is replaced by an aryl group. Aralkyl includes groups in which more than one hydrogen atom has been replaced by an aryl group. Examples of “arylalkyl” or “aralkyl” include benzyl, 2-phenylethyl, 3-phenylpropyl, 9-fluorenyl, benzhydryl, and trityl groups.

As used herein, “cycloalkyl” refers to a cyclic, bicyclic, tricyclic, or polycyclic non-aromatic hydrocarbon groups having 3 to 12 carbons. Examples of cycloalkyl moieties include, but are not limited to, cyclopropyl, cyclopentyl, and cyclohexyl.

As used herein, “heterocyclyl” refers to a monovalent radical of a heterocyclic ring system. Representative heterocyclyls include, without limitation, tetrahydrofuranyl, tetrahydrothienyl, pyrrolidinyl, pyrrolidonyl, piperidinyl, pyrrolinyl, piperazinyl, dioxanyl, dioxolanyl, diazepinyl, oxazepinyl, thiazepinyl, and morpholinyl.

As used herein, “heteroaryl” refers to a monovalent radical of a heteroaromatic ring system. Examples of heteroaryl moieties include, but are not limited to, imidazolyl, oxazolyl, thiazolyl, triazolyl, pyrrolyl, furanyl, indolyl, thiophenyl pyrazolyl, pyridinyl, pyrazinyl, pyridazinyl, pyrimidinyl, indolizinyl, purinyl, naphthyridinyl, quinolyl, and pteridinyl.

Phosphate Backbone Modifications

The Phosphate Group

In an embodiment, the phosphate group of a modified nucleotide can be modified by replacing one or more of the oxygens with a different substituent. Further, the modified nucleotide, e.g., modified nucleotide present in a modified nucleic acid, can include the wholesale replacement of an unmodified phosphate moiety with a modified phosphate as described herein. In an embodiment, the modification of the phosphate backbone can include alterations that result in either an uncharged linker or a charged linker with unsymmetrical charge distribution.

Examples of modified phosphate groups include, phosphorothioate, phosphoroselenates, borano phosphates, borano phosphate esters, hydrogen phosphonates, phosphoroamidates, alkyl or aryl phosphonates and phosphotriesters. In an embodiment, one of the non-bridging phosphate oxygen atoms in the phosphate backbone moiety can be replaced by any of the following groups: sulfur (S), selenium (Se), BR₃ (wherein R can be, e.g., hydrogen, alkyl, or aryl), C (e.g., an alkyl group, an aryl group, and the like), H, NR₂ (wherein R can be, e.g., hydrogen, alkyl, or aryl), or OR (wherein R can be, e.g., alkyl or aryl). The phosphorous atom in an unmodified phosphate group is achiral. However, replacement of one of the non-bridging oxygens with one of the above atoms or groups of atoms can render the phosphorous atom chiral; that is to say that a phosphorous atom in a phosphate group modified in this way is a stereogenic center. The stereogenic phosphorous atom can possess either the “R” configuration (herein Rp) or the “S” configuration (herein Sp).

Phosphorodithioates have both non-bridging oxygens replaced by sulfur. The phosphorus center in the phosphorodithioates is achiral which precludes the formation of oligoribonucleotide diastereomers. In an embodiment, modifications to one or both non-bridging oxygens can also include the replacement of the non-bridging oxygens with a group independently selected from S, Se, B, C, H, N, and OR (R can be, e.g., alkyl or aryl).

The phosphate linker can also be modified by replacement of a bridging oxygen, (i.e., the oxygen that links the phosphate to the nucleoside), with nitrogen (bridged phosphoroamidates), sulfur (bridged phosphorothioates) and carbon (bridged methylenephosphonates). The replacement can occur at either linking oxygen or at both of the linking oxygens.

Replacement of the Phosphate Group

The phosphate group can be replaced by non-phosphorus containing connectors. In an embodiment, the charge phosphate group can be replaced by a neutral moiety.

Examples of moieties which can replace the phosphate group can include, without limitation, e.g., methyl phosphonate, hydroxylamino, siloxane, carbonate, carboxymethyl, carbamate, amide, thioether, ethylene oxide linker, sulfonate, sulfonamide, thioformacetal, formacetal, oxime, methyleneimino, methylenemethylimino, methylenehydrazo, methylenedimethylhydrazo and methyleneoxymethylimino.

Replacement of the Ribophosphate Backbone

Scaffolds that can mimic nucleic acids can also be constructed wherein the phosphate linker and ribose sugar are replaced by nuclease resistant nucleoside or nucleotide surrogates. In an embodiment, the nucleobases can be tethered by a surrogate backbone. Examples can include, without limitation, the morpholino, cyclobutyl, pyrrolidine and peptide nucleic acid (PNA) nucleoside surrogates.

Sugar Modifications

The modified nucleosides and modified nucleotides can include one or more modifications to the sugar group. For example, the 2′ hydroxyl group (OH) can be modified or replaced with a number of different “oxy” or “deoxy” substituents. In an embodiment, modifications to the 2′ hydroxyl group can enhance the stability of the nucleic acid since the hydroxyl can no longer be deprotonated to form a 2′-alkoxide ion. The 2′-alkoxide can catalyze degradation by intramolecular nucleophilic attack on the linker phosphorus atom.

Examples of “oxy”-2′ hydroxyl group modifications can include alkoxy or aryloxy (OR, wherein “R” can be, e.g., alkyl, cycloalkyl, aryl, aralkyl, heteroaryl or a sugar); polyethyleneglycols (PEG), O(CH₂CH₂O)_(n)CH₂CH₂OR wherein R can be, e.g., H or optionally substituted alkyl, and n can be an integer from 0 to 20 (e.g., from 0 to 4, from 0 to 8, from 0 to 10, from 0 to 16, from 1 to 4, from 1 to 8, from 1 to 10, from 1 to 16, from 1 to 20, from 2 to 4, from 2 to 8, from 2 to 10, from 2 to 16, from 2 to 20, from 4 to 8, from 4 to 10, from 4 to 16, and from 4 to 20). In an embodiment, the “oxy”-2′ hydroxyl group modification can include “locked” nucleic acids (LNA) in which the 2′ hydroxyl can be connected, e.g., by a C₁₋₆ alkylene or C₁₋₆ heteroalkylene bridge, to the 4′ carbon of the same ribose sugar, where exemplary bridges can include methylene, propylene, ether, or amino bridges; O-amino (wherein amino can be, e.g., NH₂; alkylamino, dialkylamino, heterocyclyl, arylamino, diarylamino, heteroarylamino, or diheteroarylamino, ethylenediamine, or polyamino) and aminoalkoxy, O(CH₂)_(n)-amino, (wherein amino can be, e.g., NH₂; alkylamino, dialkylamino, heterocyclyl, arylamino, diarylamino, heteroarylamino, or diheteroarylamino, ethylenediamine, or polyamino). In an embodiment, the “oxy”-2′ hydroxyl group modification can include the methoxyethyl group (MOE), (OCH₂CH₂OCH₃, e.g., a PEG derivative).

“Deoxy” modifications can include hydrogen (i.e. deoxyribose sugars, e.g., at the overhang portions of partially ds RNA); halo (e.g., bromo, chloro, fluoro, or iodo); amino (wherein amino can be, e.g., NH₂; alkylamino, dialkylamino, heterocyclyl, arylamino, diarylamino, heteroarylamino, diheteroarylamino, or amino acid); NH(CH₂CH₂NH)_(n)CH₂CH₂-amino (wherein amino can be, e.g., as described herein), —NHC(O)R (wherein R can be, e.g., alkyl, cycloalkyl, aryl, aralkyl, heteroaryl or sugar), cyano; mercapto; alkyl-thio-alkyl; thioalkoxy; and alkyl, cycloalkyl, aryl, alkenyl and alkynyl, which may be optionally substituted with e.g., an amino as described herein.

The sugar group can also contain one or more carbons that possess the opposite stereochemical configuration than that of the corresponding carbon in ribose. Thus, a modified nucleic acid can include nucleotides containing e.g., arabinose, as the sugar. The nucleotide “monomer” can have an alpha linkage at the 1′ position on the sugar, e.g., alpha-nucleosides. The modified nucleic acids can also include “abasic” sugars, which lack a nucleobase at C-1′. These abasic sugars can also be further modified at one or more of the constituent sugar atoms. The modified nucleic acids can also include one or more sugars that are in the L form, e.g. L-nucleosides.

Generally, RNA includes the sugar group ribose, which is a 5-membered ring having an oxygen. Exemplary modified nucleosides and modified nucleotides can include, without limitation, replacement of the oxygen in ribose (e.g., with sulfur (S), selenium (Se), or alkylene, such as, e.g., methylene or ethylene); addition of a double bond (e.g., to replace ribose with cyclopentenyl or cyclohexenyl); ring contraction of ribose (e.g., to form a 4-membered ring of cyclobutane or oxetane); ring expansion of ribose (e.g., to form a 6- or 7-membered ring having an additional carbon or heteroatom, such as for example, anhydrohexitol, altritol, mannitol, cyclohexanyl, cyclohexenyl, and morpholino that also has a phosphoramidate backbone). In an embodiment, the modified nucleotides can include multicyclic forms (e.g., tricyclo; and “unlocked” forms, such as glycol nucleic acid (GNA) (e.g., R-GNA or S-GNA, where ribose is replaced by glycol units attached to phosphodiester bonds), threose nucleic acid (TNA, where ribose is replaced with α-L-threofuranosyl-(3′→2′)).

Modifications on the Nucleobase

The modified nucleosides and modified nucleotides described herein, which can be incorporated into a modified nucleic acid, can include a modified nucleobase. Examples of nucleobases include, but are not limited to, adenine (A), guanine (G), cytosine (C), and uracil (U). These nucleobases can be modified or wholly replaced to provide modified nucleosides and modified nucleotides that can be incorporated into modified nucleic acids. The nucleobase of the nucleotide can be independently selected from a purine, a pyrimidine, a purine or pyrimidine analog. In an embodiment, the nucleobase can include, for example, naturally-occurring and synthetic derivatives of a base.

Uracil

In an embodiment, the modified nucleobase is a modified uracil. Exemplary nucleobases and nucleosides having a modified uracil include without limitation pseudouridine (ψ), pyridin-4-one ribonucleoside, 5-aza-uridine, 6-aza-uridine, 2-thio-5-aza-uridine, 2-thio-uridine (s2U), 4-thio-uridine (s4U), 4-thio-pseudouridine, 2-thio-pseudouridine, 5-hydroxy-uridine (ho⁵U), 5-aminoallyl-uridine, 5-halo-uridine (e.g., 5-iodo-uridine or 5-bromo-uridine), 3-methyl-uridine (m³U), 5-methoxy-uridine (mo⁵U), uridine 5-oxyacetic acid (cmo⁵U), uridine 5-oxyacetic acid methyl ester (memo⁵U), 5-carboxymethyl-uridine (cm⁵U), 1-carboxymethyl-pseudouridine, 5-carboxyhydroxymethyl-uridine (chm⁵U), 5-carboxyhydroxymethyl-uridine methyl ester (mchm⁵U), 5-methoxycarbonylmethyl-uridine (mcm⁵U), 5-methoxycarbonylmethyl-2-thio-uridine (mcm⁵s2U), 5-aminomethyl-2-thio-uridine (nm⁵s2U), 5-methylaminomethyl-uridine (mnm⁵U), 5-methylaminomethyl-2-thio-uridine (mnm⁵s2U), 5-methylaminomethyl-2-seleno-uridine (mnm⁵se²U), 5-carbamoylmethyl-uridine (ncm⁵U), 5-carboxymethylaminomethyl-uridine (cmnm⁵U), 5-carboxymethylaminomethyl-2-thio-uridine (cmnm⁵s2U), 5-propynyl-uridine, 1-propynyl-pseudouridine, 5-taurinomethyl-uridine (τCm⁵U), 1-taurinomethyl-pseudouridine, 5-taurinomethyl-2-thio-uridine(τm⁵s2U), 1-taurinomethyl-4-thio-pseudouridine, 5-methyl-uridine (m⁵U, i.e., having the nucleobase deoxythymine), 1-methyl-pseudouridine (m¹ψ), 5-methyl-2-thio-uridine (m⁵s2U), 1-methyl-4-thio-pseudouridine (m¹s⁴ψ), 4-thio-1-methyl-pseudouridine, 3-methyl-pseudouridine (m³ψ), 2-thio-1-methyl-pseudouridine, 1-methyl-1-deaza-pseudouridine, 2-thio-1-methyl-1-deaza-pseudouridine, dihydrouridine (D), dihydropseudouridine, 5,6-dihydrouridine, 5-methyl-dihydrouridine (m⁵D), 2-thio-dihydrouridine, 2-thio-dihydropseudouridine, 2-methoxy-uridine, 2-methoxy-4-thio-uridine, 4-methoxy-pseudouridine, 4-methoxy-2-thio-pseudouridine, N1-methyl-pseudouridine, 3-(3-amino-3-carboxypropyl)uridine (acp³U), 1-methyl-3-(3-amino-3-carboxypropyl)pseudouridine (acp³ψ), 5-(isopentenylaminomethyl)uridine (inm⁵U), 5-(isopentenylaminomethyl)-2-thio-uridine (inm⁵s2U), α-thio-uridine, 2′-O-methyl-uridine (Um), 5,2′-O-dimethyl-uridine (m⁵Um), 2′-O-methyl-pseudouridine (Wm), 2-thio-2′-O-methyl-uridine (s2Um), 5-methoxycarbonylmethyl-2′-O-methyl-uridine (mcm⁵Um), 5-carbamoylmethyl-2′-O-methyl-uridine (ncm ⁵Um), 5-carboxymethylaminomethyl-2′-O-methyl-uridine (cmnm ⁵Um), 3,2′-O-dimethyl-uridine (m³Um), 5-(isopentenylaminomethyl)-2′-O-methyl-uridine (inm⁵Um), 1-thio-uridine, deoxythymidine, 2′-F-ara-uridine, 2′-F-uridine, 2′-OH-ara-uridine, 5-(2-carbomethoxyvinyl) uridine, 5-[3-(1-E-propenylamino)uridine, pyrazolo[3,4-d]pyrimidines, xanthine, and hypoxanthine.

Cytosine

In an embodiment, the modified nucleobase is a modified cytosine. Exemplary nucleobases and nucleosides having a modified cytosine include without limitation 5-aza-cytidine, 6-aza-cytidine, pseudoisocytidine, 3-methyl-cytidine (m³C), N4-acetyl-cytidine (act), 5-formyl-cytidine (f⁵C), N4-methyl-cytidine (m⁴C), 5-methyl-cytidine (m⁵C), 5-halo-cytidine (e.g., 5-iodo-cytidine), 5-hydroxymethyl-cytidine (hm⁵C), 1-methyl-pseudoisocytidine, pyrrolo-cytidine, pyrrolo-pseudoisocytidine, 2-thio-cytidine (s2C), 2-thio-5-methyl-cytidine, 4-thio-pseudoisocytidine, 4-thio-1-methyl-pseudoisocytidine, 4-thio-1-methyl-1-deaza-pseudoisocytidine, 1-methyl-1-deaza-pseudoisocytidine, zebularine, 5-aza-zebularine, 5-methyl-zebularine, 5-aza-2-thio-zebularine, 2-thio-zebularine, 2-methoxy-cytidine, 2-methoxy-5-methyl-cytidine, 4-methoxy-pseudoisocytidine, 4-methoxy-1-methyl-pseudoisocytidine, lysidine (k²C), α-thio-cytidine, 2′-O-methyl-cytidine (Cm), 5,2′-O-dimethyl-cytidine (m⁵Cm), N4-acetyl-2′-O-methyl-cytidine (ac⁴Cm), N4,2′-O-dimethyl-cytidine (m⁴Cm), 5-formyl-2′-O-methyl-cytidine (f ⁵Cm), N4,N4,2′-O-trimethyl-cytidine (m⁴ ₂Cm), 1-thio-cytidine, 2′-F-ara-cytidine, 2′-F-cytidine, and 2′-OH-ara-cytidine.

Adenine

In an embodiment, the modified nucleobase is a modified adenine. Exemplary nucleobases and nucleosides having a modified adenine include without limitation 2-amino-purine, 2,6-diaminopurine, 2-amino-6-halo-purine (e.g., 2-amino-6-chloro-purine), 6-halo-purine (e.g., 6-chloro-purine), 2-amino-6-methyl-purine, 8-azido-adenosine, 7-deaza-adenosine, 7-deaza-8-aza-adenosine, 7-deaza-2-amino-purine, 7-deaza-8-aza-2-amino-purine, 7-deaza-2,6-diaminopurine, 7-deaza-8-aza-2,6-diaminopurine, 1-methyl-adenosine (m¹A), 2-methyl-adenosine (m²A), N6-methyl-adenosine (m⁶A), 2-methylthio-N6-methyl-adenosine (ms2m⁶A), N6-isopentenyl-adenosine (i⁶A), 2-methylthio-N6-isopentenyl-adenosine (ms²i⁶A), N6-(cis-hydroxyisopentenyl)adenosine (io⁶A), 2-methylthio-N6-(cis-hydroxyisopentenyl)adenosine (ms2io⁶A), N6-glycinylcarbamoyl-adenosine (g⁶A), N6-threonylcarbamoyl-adenosine (t⁶A), N6-methyl-N6-threonylcarbamoyl-adenosine (m⁶t⁶A), 2-methylthio-N6-threonylcarbamoyl-adenosine (ms²g⁶A), N6,N6-dimethyl-adenosine (m⁶ ₂A), N6-hydroxynorvalylcarbamoyl-adenosine (hn⁶A), 2-methylthio-N6-hydroxynorvalylcarbamoyl-adenosine (ms2hn⁶A), N6-acetyl-adenosine (ac⁶A), 7-methyl-adenosine, 2-methylthio-adenosine, 2-methoxy-adenosine, α-thio-adenosine, 2′-O-methyl-adenosine (Am), N⁶,2′-O-dimethyl-adenosine (m⁶Am), N⁶-Methyl-2′-deoxyadenosine, N6,N6,2′-O-trimethyl-adenosine (m⁶ ₂Am), 1,2′-O-dimethyl-adenosine (m¹Am), 2′-O-ribosyladenosine (phosphate) (Ar(p)), 2-amino-N6-methyl-purine, 1-thio-adenosine, 8-azido-adenosine, 2′-F-ara-adenosine, 2′-F-adenosine, 2′-OH-ara-adenosine, and N6-(19-amino-pentaoxanonadecyl)-adenosine.

Guanine

In an embodiment, the modified nucleobase is a modified guanine. Exemplary nucleobases and nucleosides having a modified guanine include without limitation inosine (I), 1-methyl-inosine (m¹I), wyosine (imG), methylwyosine (mimG), 4-demethyl-wyosine (imG-14), isowyosine (imG2), wybutosine (yW), peroxywybutosine (o₂yW), hydroxywybutosine (OHyW), undermodified hydroxywybutosine (OHyW*), 7-deaza-guanosine, queuosine (Q), epoxyqueuosine (oQ), galactosyl-queuosine (galQ), mannosyl-queuosine (manQ), 7-cyano-7-deaza-guanosine (preQ₀), 7-aminomethyl-7-deaza-guanosine (preQ₁), archaeosine (G⁺), 7-deaza-8-aza-guanosine, 6-thio-guanosine, 6-thio-7-deaza-guanosine, 6-thio-7-deaza-8-aza-guanosine, 7-methyl-guanosine (m⁷G), 6-thio-7-methyl-guanosine, 7-methyl-inosine, 6-methoxy-guanosine, 1-methyl-guanosine (m′G), N2-methyl-guanosine (m²G), N2,N2-dimethyl-guanosine (m² 2G), N2,7-dimethyl-guanosine (m²,7G), N2, N2,7-dimethyl-guanosine (m²,2,7G), 8-oxo-guanosine, 7-methyl-8-oxo-guanosine, 1-methyl-6- thio-guanosine, N2-methyl-6-thio-guanosine, N2,N2-dimethyl-6-thio-guanosine, α-thio-guanosine, 2′-O-methyl-guanosine (Gm), N2-methyl-2′-O-methyl-guanosine (m²Gm), N2,N2-dimethyl-2′-O-methyl-guanosine (m² 2Gm), 1-methyl-2′-O-methyl-guanosine (m′Gm), N2,7-dimethyl-2′-O-methyl-guanosine (m²,7Gm), 2′-O-methyl-inosine (Im), 1,2′-O-dimethyl-inosine (m′Im), O⁶-phenyl-2′-deoxyinosine, 2′-O-ribosylguanosine (phosphate) (Gr(p)), 1-thio-guanosine, O⁶-methyl-guanosine, O⁶-Methyl-2′-deoxyguanosine, 2′-F-ara-guanosine, and 2′-F-guanosine.

Exemplary Modified gRNAs

In some embodiments, the modified nucleic acids can be modified gRNAs. It is to be understood that any of the gRNAs described herein can be modified in accordance with this section, including any gRNA that comprises a targeting domain from Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or 31.

As discussed above, transiently expressed or delivered nucleic acids can be prone to degradation by, e.g., cellular nucleases. Accordingly, in one aspect the modified gRNAs described herein can contain one or more modified nucleosides or nucleotides which introduce stability toward nucleases. While not wishing to be bound by theory it is also believed that certain modified gRNAs described herein can exhibit a reduced innate immune response when introduced into a population of cells, particularly the cells of the present invention. As noted above, the term “innate immune response” includes a cellular response to exogenous nucleic acids, including single stranded nucleic acids, generally of viral or bacterial origin, which involves the induction of cytokine expression and release, particularly the interferons, and cell death.

While some of the exemplary modification discussed in this section may be included at any position within the gRNA sequence, in some embodiments, a gRNA comprises a modification at or near its 5′ end (e.g., within 1-10, 1-5, or 1-2 nucleotides of its 5′ end). In some embodiments, a gRNA comprises a modification at or near its 3′ end (e.g., within 1-10, 1-5, or 1-2 nucleotides of its 3′ end). In some embodiments, a gRNA comprises both a modification at or near its 5′ end and a modification at or near its 3′ end.

In an embodiment, the 5′ end of a gRNA is modified by the inclusion of a eukaryotic mRNA cap structure or cap analog (e.g., a G(5′)ppp(5′)G cap analog, a m7G(5′)ppp(5′)G cap analog, or a 3′-O-Me-m7G(5′)ppp(5′)G anti reverse cap analog (ARCA)). The cap or cap analog can be included during either chemical synthesis or in vitro transcription of the gRNA.

In an embodiment, an in vitro transcribed gRNA is modified by treatment with a phosphatase (e.g., calf intestinal alkaline phosphatase) to remove the 5′ triphosphate group.

In an embodiment, the 3′ end of a gRNA is modified by the addition of one or more (e.g., 25-200) adenine (A) residues. The polyA tract can be contained in the nucleic acid (e.g., plasmid, PCR product, viral genome) encoding the gRNA, or can be added to the gRNA during chemical synthesis, or following in vitro transcription using a polyadenosine polymerase (e.g., E. coli Poly(A)Polymerase).

In an embodiment, in vitro transcribed gRNA contains both a 5′ cap structure or cap analog and a 3′ polyA tract. In an embodiment, an in vitro transcribed gRNA is modified by treatment with a phosphatase (e.g., calf intestinal alkaline phosphatase) to remove the 5′ triphosphate group and comprises a 3′ polyA tract.

In some embodiments, gRNAs can be modified at a 3′ terminal U ribose. For example, the two terminal hydroxyl groups of the U ribose can be oxidized to aldehyde groups and a concomitant opening of the ribose ring to afford a modified nucleoside as shown below:

wherein “U” can be an unmodified or modified uridine.

In another embodiment, the 3′ terminal U can be modified with a 2′3′ cyclic phosphate as shown below:

wherein “U” can be an unmodified or modified uridine.

In some embodiments, the gRNA molecules may contain 3′ nucleotides which can be stabilized against degradation, e.g., by incorporating one or more of the modified nucleotides described herein. In this embodiment, e.g., uridines can be replaced with modified uridines, e.g., 5-(2-amino)propyl uridine, and 5-bromo uridine, or with any of the modified uridines described herein; adenosines and guanosines can be replaced with modified adenosines and guanosines, e.g., with modifications at the 8-position, e.g., 8-bromo guanosine, or with any of the modified adenosines or guanosines described herein.

In some embodiments, sugar-modified ribonucleotides can be incorporated into the gRNA, e.g., wherein the 2′ OH-group is replaced by a group selected from H, —OR, —R (wherein R can be, e.g., alkyl, cycloalkyl, aryl, aralkyl, heteroaryl or sugar), halo, —SH, —SR (wherein R can be, e.g., alkyl, cycloalkyl, aryl, aralkyl, heteroaryl or sugar), amino (wherein amino can be, e.g., NH₂; alkylamino, dialkylamino, heterocyclyl, arylamino, diarylamino, heteroarylamino, diheteroarylamino, or amino acid); or cyano (—CN). In some embodiments, the phosphate backbone can be modified as described herein, e.g., with a phosphothioate group. In some embodiments, one or more of the nucleotides of the gRNA can each independently be a modified or unmodified nucleotide including, but not limited to 2′-sugar modified, such as, 2′-O-methyl, 2′-O-methoxyethyl, or 2′-Fluoro modified including, e.g., 2′-F or 2′-O-methyl, adenosine (A), 2′-F or 2′-O-methyl, cytidine (C), 2′-F or 2′-O-methyl, uridine (U), 2′-F or 2′-O-methyl, thymidine (T), 2′-F or 2′-O-methyl, guanosine (G), 2′-O-methoxyethyl-5-methyluridine (Teo), 2′-O-methoxyethyladenosine (Aeo), 2′-O-methoxyethyl-5-methylcytidine (m5Ceo), and any combinations thereof.

In some embodiments, a gRNA can include “locked” nucleic acids (LNA) in which the 2′ OH-group can be connected, e.g., by a C1-6 alkylene or C1-6 heteroalkylene bridge, to the 4′ carbon of the same ribose sugar, where exemplary bridges can include methylene, propylene, ether, or amino bridges; O-amino (wherein amino can be, e.g., NH₂; alkylamino, dialkylamino, heterocyclyl, arylamino, diarylamino, heteroarylamino, or diheteroarylamino, ethylenediamine, or polyamino) and aminoalkoxy or O(CH₂)_(n)-amino (wherein amino can be, e.g., NH₂; alkylamino, dialkylamino, heterocyclyl, arylamino, diarylamino, heteroarylamino, or diheteroarylamino, ethylenediamine, or polyamino).

In some embodiments, a gRNA can include a modified nucleotide which is multicyclic (e.g., tricyclo; and “unlocked” forms, such as glycol nucleic acid (GNA) (e.g., R-GNA or S-GNA, where ribose is replaced by glycol units attached to phosphodiester bonds), or threose nucleic acid (TNA, where ribose is replaced with α-L-threofuranosyl-(3′→2′)).

Generally, gRNA molecules include the sugar group ribose, which is a 5-membered ring having an oxygen. Exemplary modified gRNAs can include, without limitation, replacement of the oxygen in ribose (e.g., with sulfur (S), selenium (Se), or alkylene, such as, e.g., methylene or ethylene); addition of a double bond (e.g., to replace ribose with cyclopentenyl or cyclohexenyl); ring contraction of ribose (e.g., to form a 4-membered ring of cyclobutane or oxetane); ring expansion of ribose (e.g., to form a 6- or 7-membered ring having an additional carbon or heteroatom, such as for example, anhydrohexitol, altritol, mannitol, cyclohexanyl, cyclohexenyl, and morpholino that also has a phosphoramidate backbone). Although the majority of sugar analog alterations are localized to the 2′ position, other sites are amenable to modification, including the 4′ position. In an embodiment, a gRNA comprises a 4′-S, 4′-Se or a 4′-C-aminomethyl-2′-O-Me modification.

In some embodiments, deaza nucleotides, e.g., 7-deaza-adenosine, can be incorporated into the gRNA. In some embodiments, O- and N-alkylated nucleotides, e.g., N6-methyl adenosine, can be incorporated into the gRNA. In some embodiments, one or more or all of the nucleotides in a gRNA molecule are deoxynucleotides.

miRNA Binding Sites

microRNAs (or miRNAs) are naturally occurring cellular 19-25 nucleotide long noncoding RNAs. They bind to nucleic acid molecules having an appropriate miRNA binding site, e.g., in the 3′ UTR of an mRNA, and down-regulate gene expression. While not wishing to be bound by theory it is believed that the down regulation is either by reducing nucleic acid molecule stability or by inhibiting translation. An RNA species disclosed herein, e.g., an mRNA encoding Cas9 can comprise an miRNA binding site, e.g., in its 3′UTR. The miRNA binding site can be selected to promote down regulation of expression is a selected cell type. By way of example, the incorporation of a binding site for miR-122, a microRNA abundant in liver, can inhibit the expression of the gene of interest in the liver.

EXAMPLES

The following Examples are merely illustrative and are not intended to limit the scope or content of the invention in any way.

Example 1: Cloning and Initial Screening of gRNAs

The suitability of candidate gRNAs can be evaluated as described in this example. Although described for a chimeric gRNA, the approach can also be used to evaluate modular gRNAs.

Cloning gRNAs into Vectors

For each gRNA, a pair of overlapping oligonucleotides is designed and obtained. Oligonucleotides are annealed and ligated into a digested vector backbone containing an upstream U6 promoter and the remaining sequence of a long chimeric gRNA. Plasmid is sequence-verified and prepped to generate sufficient amounts of transfection-quality DNA. Alternate promoters maybe used to drive in vivo transcription (e.g. H1 promoter) or for in vitro transcription (e.g., a T7 promoter).

Cloning gRNAs in Linear dsDNA Molecule (STITCHR)

For each gRNA, a single oligonucleotide is designed and obtained. The U6 promoter and the gRNA scaffold (e.g. including everything except the targeting domain, e.g., including sequences derived from the crRNA and tracrRNA, e.g., including a first complementarity domain; a linking domain; a second complementarity domain; a proximal domain; and a tail domain) are separately PCR amplified and purified as dsDNA molecules. The gRNA-specific oligonucleotide is used in a PCR reaction to stitch together the U6 and the gRNA scaffold, linked by the targeting domain specified in the oligonucleotide. Resulting dsDNA molecule (STITCHR product) is purified for transfection. Alternate promoters may be used to drive in vivo transcription (e.g., H1 promoter) or for in vitro transcription (e.g., T7 promoter). Any gRNA scaffold may be used to create gRNAs compatible with Cas9s from any bacterial species.

Initial gRNA Screen

Each gRNA to be tested is transfected, along with a plasmid expressing Cas9 and a small amount of a GFP-expressing plasmid into human cells. In preliminary experiments, these cells can be immortalized human cell lines such as 293T, K562 or U2OS. Alternatively, primary human cells may be used. In this case, cells may be relevant to the eventual therapeutic cell target (for example, an erythroid cell). The use of primary cells similar to the potential therapeutic target cell population may provide important information on gene targeting rates in the context of endogenous chromatin and gene expression.

Transfection may be performed using lipid transfection (such as Lipofectamine or Fugene) or by electroporation (such as Lonza Nucleofection). Following transfection, GFP expression can be determined either by fluorescence microscopy or by flow cytometry to confirm consistent and high levels of transfection. These preliminary transfections can comprise different gRNAs and different targeting approaches (17-mers, 20-mers, nuclease, dual-nickase, etc.) to determine which gRNAs/combinations of gRNAs give the greatest activity.

Efficiency of cleavage with each gRNA may be assessed by measuring NHEJ-induced indel formation at the target locus by a T7E1-type assay or by sequencing. Alternatively, other mismatch-sensitive enzymes, such as Cell/Surveyor nuclease, may also be used.

For the T7E1 assay, PCR amplicons are approximately 500-700 bp with the intended cut site placed asymmetrically in the amplicon. Following amplification, purification and size-verification of PCR products, DNA is denatured and re-hybridized by heating to 95° C. and then slowly cooling. Hybridized PCR products are then digested with T7 Endonuclease I (or other mismatch-sensitive enzyme) which recognizes and cleaves non-perfectly matched DNA. If indels are present in the original template DNA, when the amplicons are denatured and re-annealed, this results in the hybridization of DNA strands harboring different indels and therefore lead to double-stranded DNA that is not perfectly matched. Digestion products may be visualized by gel electrophoresis or by capillary electrophoresis. The fraction of DNA that is cleaved (density of cleavage products divided by the density of cleaved and uncleaved) may be used to estimate a percent NHEJ using the following equation: % NHEJ=(1−(1−fraction cleaved)½). The T7E1 assay is sensitive down to about 2-5% NHEJ.

Sequencing may be used instead of, or in addition to, the T7E1 assay. For Sanger sequencing, purified PCR amplicons are cloned into a plasmid backbone, transformed, miniprepped and sequenced with a single primer. Sanger sequencing may be used for determining the exact nature of indels after determining the NHEJ rate by T7E1.

Sequencing may also be performed using next generation sequencing techniques. When using next generation sequencing, amplicons may be 300-500 bp with the intended cut site placed asymmetrically. Following PCR, next generation sequencing adapters and barcodes (for example Illumina multiplex adapters and indexes) may be added to the ends of the amplicon, e.g., for use in high throughput sequencing (for example on an Illumina MiSeq). This method allows for detection of very low NHEJ rates.

Example 2: Assessment of Gene Targeting by NHEJ

The gRNAs that induce the greatest levels of NHEJ in initial tests can be selected for further evaluation of gene targeting efficiency. In this case, cells are derived from disease subjects and, therefore, harbor the relevant mutation.

Following transfection (usually 2-3 days post-transfection,) genomic DNA may be isolated from a bulk population of transfected cells and PCR may be used to amplify the target region. Following PCR, gene targeting efficiency to generate the desired mutations (either knockout of a target gene or removal of a target sequence motif) may be determined by sequencing. For Sanger sequencing, PCR amplicons may be 500-700 bp long. For next generation sequencing, PCR amplicons may be 300-500 bp long. If the goal is to knockout gene function, sequencing may be used to assess what percent of alleles have undergone NHEJ-induced indels that result in a frameshift or large deletion or insertion that would be expected to destroy gene function. If the goal is to remove a specific sequence motif, sequencing may be used to assess what percent of alleles have undergone NHEJ-induced deletions that span this sequence.

Example 3: Assessment of Gene Targeting by HDR

The gRNAs that induce the greatest levels of NHEJ in initial tests can be selected for further evaluation of gene targeting efficiency. In this case, cells are derived from disease subjects and, therefore, harbor the relevant mutation.

Following transfection (usually 2-3 days post-transfection,) genomic DNA may be isolated from a bulk population of transfected cells and PCR may be used to amplify the target region. Following PCR, gene targeting efficiency can be determined by several methods.

Determination of gene targeting frequency involves measuring the percentage of alleles that have undergone homologous directed repair (HDR) with the exogenously provided donor template or endogenous genomic donor sequence and which therefore have incorporated the desired correction. If the desired HDR event creates or destroys a restriction enzyme site, the frequency of gene targeting may be determined by a RFLP assay. If no restriction site is created or destroyed, sequencing may be used to determine gene targeting frequency. If a RFLP assay is used, sequencing may still be used to verify the desired HDR event and ensure that no other mutations are present. If an exogenously provided donor template is employed, at least one of the primers is placed in the endogenous gene sequence outside of the region included in the homology arms, which prevents amplification of donor template still present in the cells. Therefore, the length of the homology arms present in the donor template may affect the length of the PCR amplicon. PCR amplicons can either span the entire donor region (both primers placed outside the homology arms) or they can span only part of the donor region and a single junction between donor and endogenous DNA (one internal and one external primer). If the amplicons span less than the entire donor region, two different PCRs should be used to amplify and sequence both the 5′ and the 3′ junction.

If the PCR amplicon is short (less than 600 bp) it is possible to use next generation sequencing. Following PCR, next generation sequencing adapters and barcodes (for example Illumina multiplex adapters and indexes) may be added to the ends of the amplicon, e.g., for use in high throughput sequencing (for example on an Illumina MiSeq). This method allows for detection of very low gene targeting rates.

If the PCR amplicon is too long for next generation sequencing, Sanger sequencing can be performed. For Sanger sequencing, purified PCR amplicons will be cloned into a plasmid backbone (for example, TOPO cloned using the LifeTech Zero Blunt® TOPO® cloning kit), transformed, miniprepped and sequenced.

The same or similar assays described above can be used to measure the percentage of alleles that have undergone HDR with endogenous genomic donor sequence and which therefore have incorporated the desired correction.

Example 4: Screening of gRNAs for Targeting BCL11A

In order to identify gRNAs with the highest on target NHEJ efficiency, thirty exemplary S. pyogenes gRNAs were selected for testing (Table 31). The gRNAs tested target three different regions of the BCL11A locus—5′ of a red blood cell enhancer, 3′ of a red blood cell enhancer and downstream of the ATG start codon in exon 2 (specified in Table 31).

TABLE 31 gRNA Name Targeting Sequence Size Gene Region SEQ ID NO BCL11A-2981W GUGCUACUUAUACAAUUCAC 20 3′ of enhancer 16261 BCL11A-2982W GAAAAUACUUACUGUACUGC 20 3′ of enhancer 16262 BCL11A-2983W GGCUGUUUUGGAAUGUAGAG 20 5′ of enhancer 16263 BCL11A-2984W AUUCACUGGAAACCCUGUUA 20 3′ of enhancer 16264 BCL11A-2985W UACUGUACUGCAGGGGAAUU 20 3′ of enhancer 16265 BCL11A-2986W AAACUAUUUACAGCCAUAAC 20 3′ of enhancer 16266 BCL11A-2987W AAAUACUUACUGUACUGCAG 20 3′ of enhancer 16267 BCL11A-2988W CUAUUUACAGCCAUAAC 17 3′ of enhancer 16268 BCL11A-2989W CUACUUAUACAAUUCAC 17 3′ of enhancer 16269 BCL11A-2990W CACUGGAAACCCUGUUA 17 3′ of enhancer 16270 BCL11A-2991W UACUUACUGUACUGCAG 17 3′ of enhancer 16271 BCL11A-2992W UGUACUGCAGGGGAAUU 17 3′ of enhancer 16272 BCL11A-2993W AAUACUUACUGUACUGC 17 3′of enhancer 16273 BCL11A-2994W AUACUUACUGUACUGCA 17 3′ of enhancer 16274 BCL11A-2995W GAAUGUAGAGAGGCAGA 17 5′ of enhancer 16275 BCL11A-2996W GGAAUGUAGAGAGGCAG 17 5′ of enhancer 16276 BCL11A-2997W GUAAGUAUUUUCUUUCAUUG 20 3′ of enhancer 16277 BCL11A-2998W GUAAUUAAGAAAGCAGUGUA 20 5′ of enhancer 16278 BCL11A-2999W GUAUUUUCUUUCAUUGG 17 3′ of enhancer 16279 BCL11A-32W UGGCAUCCAGGUCACGCCAG 20 Exon 2 16280 BCL11A-40W GAUGCUUUUUUCAUCUCGAU 20 Exon 2 16281 BCL11A-30W GCAUCCAAUCCCGUGGAGGU 20 Exon 2 16282 BCL11A-42W UUUUCAUCUCGAUUGGUGAA 20 Exon 2 16283 BCL11A-24W CCAGAUGAACUUCCCAUUGG 20 Exon 2 16284 BCL11A-53W AGGAGGUCAUGAUCCCCUUC 20 Exon 2 16285 BCL11A-79W CAUCCAGGUCACGCCAG 17 Exon 2 16286 BCL11A-90W GCUUUUUUCAUCUCGAU 17 Exon 2 16287 BCL11A-77W UCCAAUCCCGUGGAGGU 17 Exon 2 16288 BCL11A-92W UCAUCUCGAUUGGUGAA 17 Exon 2 16289 BCL11A-71W GAUGAACUUCCCAUUGG 17 Exon 2 16290

A DNA template comprised of an exemplary gRNA (including the target region and the S. pyogenes TRACR sequence) under the control of a U6 promoter was generated by a PCR StitchR reaction. This DNA template was subsequently transfected into 293 cells using Lipofectamine 3000 along with a DNA plasmid encoding the S. pyogenes Cas9 downstream of a CMV promoter. Genomic DNA was isolated from the cells 48-72 hours post transfection. To determine the rate of modification at the BCL11A locus, the target region was amplified using a locus PCR with the primers listed in Table 32.

TABLE 32 Primer Sequence Exon TGCCTACATCTGATTCAGTGAGG (SEQ ID NO: 16291) BCL11A exon 2 5′ primer TGCCTCATTGACAAATTTGCTC (SEQ ID NO: 16292) BCL11A exon 2 3′ primer AGACCGTCTCTTTGGTGCAG (SEQ ID NO: 16293) BCL11A 5′ enhancer 5′ primer GCAGTGGCTTTAGGCTGTTT (SEQ ID NO: 16294) BCL11A 5′ enhancer 3′ primer GTGTGATCTCGGCTCACCAC (SEQ ID NO: 16295) BCL11A 3′ enhancer 5′ primer CCCTGACTTTGGAGCTCAGC (SEQ ID NO: 16296) BCL11A 3′ enhancer 3′ primer

After PCR amplification, a T7E1-directed mismatch cleavage assay was performed on the PCR product. Briefly, this assay involves melting the PCR product followed by a re-annealing step. If gene modification has occurred, there will exist double stranded products that are not perfect matches due to some frequency of insertions or deletions. These double stranded products are sensitive to cleavage by a T7 endonuclease 1 enzyme at the site of mismatch. Therefore, the efficiency of cutting by the Cas9/gRNA complex was determined by analyzing the amount of T7E1 cleavage. The formula that was used to provide a measure of % NHEJ from the T7E1 cutting is the following: 100*(1-(1-(fraction cleaved)){circumflex over ( )}0.5). The results of this analysis are shown in FIG. 11 . The top performing gRNAs in this assay were BCL11A-2981, BCL11A-2983, BCL11A-2995, BCL11A-32, BCL11A-30, and BCL11A-71.

Example 5: Deletion of the Erythroid Enhancer Elements Using Two gRNAs Flanking the Sequence

In order to test whether the erythroid enhancer sequence can be deleted using a two gRNA approach, two pairs of gRNAs were tested in 293 cells. Pair number 1 comprised BCL11A-2983W and BCL11A-2981W while Pair number 2 comprised BCL11A-2995W and BCL11A-2984W. In this example, a plasmid encoding S. pyogenes Cas9 downstream of a CMV promoter was delivered with either gRNA pair 1 or gRNA pair 2. The gRNAs were delivered as separate STITCHR products with each template comprising the U6 promoter, gRNA target sequence and S. pyogenes TRACR sequence. The DNA templates were delivered to 293 cells using lipid transfection (Lipofectamine 3000, Life Technologies). 72 hours post transfection, the cells were harvested and gDNA was isolated. To detect the deletion of the enhancer region of BCL11A, PCR primers flanking the enhancer sequences were used to amplify the deletion event. The PCR product was TOPO cloned and sequenced by Sanger sequencing. The results of these analyses are presented in FIG. 12A-13B. As shown in FIG. 12A-13B, the deletion for both gRNA pairs that were delivered to the 293 cells were detected.

Example 6: Gene Targeting of the HBB Locus by CRISPR/Cas9 to Investigate Repair Pathway Choice in Response to Different Types of DNA Lesions

The CRISPR/Cas9 system was used to target the human HBB gene in the region of the sickle cell anemia-causing mutation.

To examine how the nature of the targeted break affects the frequency of different DNA repair outcomes, blunt double-strand breaks, single-strand nicks, and dual-nicks in which the nicks are placed on opposite strands and leave either 3′ or 5′ overhangs of varying lengths, were introduced by utilizing the wild type Cas9 nuclease, as well as two different Cas9 nickases. Several different DNA repair outcomes including indel mutations resulting from non-homologous end-joining, homology-dependent repair (HDR) using the donor as a template, and HDR using the closely related HBD gene as an endogenous template, were characterized using either single-strand oligonucleotide (ssODN) or plasmid DNA donors. The frequency of these various repair outcomes under different conditions offer insight into the mechanisms of DNA repair and how it is impacted by the nature of the DNA break. The data also indicates a therapeutic approach in which correction of the sickle-cell mutation is efficiently mediated through HDR with either a donor template or with the HBD gene.

In this study different gRNA for the HBB region that surrounds the nucleotides encoding the amino acid most commonly mutated in sickle cell disease had been tested in 293T cells with wild type Cas9 molecule. The gRNAs that induced similar high rates of NHEJ and had PAMs facing in opposite orientations were selected to test as pairs with Cas9 D10A and Cas9 N863A nickases.

As shown in FIG. 14 , the gRNA pair 8/15 (“8gRNA”/“15gRNA” pair) was selected as one of the best pairs of gRNA. “8gRNA” has the targeting domain sequence of GUAACGGCAGACUUCUCCUC (SEQ ID NO: 388) and “15gRNA” has the targeting domain sequence of AAGGUGAACGUGGAUGAAGU (SEQ ID NO: 387). This pair of gRNAs in combination with the mutant Cas9 D10A would generate a 5′ overhang of 47 bp, and in combination with the mutant N863A would generate a 3′ overhang of 47 bp.

In this Example, U20S cells were electroporated with 200 ng of each gRNA and 750 ng of plasmid that encodes wild type Cas9 or mutant Cas9. Cells were collected 6 days after electroporation and genomic DNA was extracted. PCR amplification of the HBB locus was performed and subcloned into a Topo Blunt Vector. For each condition in each experiment 96 colonies were sequenced with Sanger sequencing. In the experiments assessing HDR efficacy, cells were electroporated with 2.5 ug of single stranded oligo or double stranded oligo in addition to the gRNA and the Cas9-encoding plasmid.

As shown in FIG. 15 , the total percentages of all editing events detected by Sanger sequencing of the HBB locus were similar using wild type Cas9 or Cas9 nickases (D10A, N863A).

FIGS. 16A-16B show that a majority of the total gene editing events (about 3/4 of the total) were small deletions (<10 bp). This is consistent with the notion that wildtype Cas9 generates a blunt end which are preferentially repaired by canonical NHEJ. In contrast, deletions represented only about a quarter of the total events using either nickase (D10A or N863A). Moreover, larger deletions of ˜50 bp that can be mapped to the region between the two nickase sites were observed (FIG. 16A or 16C). The remaining gene-editing events were substantially different between the two nickases.

As shown in FIG. 17A, in the case of Cas9 D10A nickase which leaves a 5′ protruding end, the lesion is mostly repaired through a mechanism defined as gene conversion. In gene conversion, the HBD locus will serve as a template to repair the HBB gene. HBD is a highly similar gene (92% identity with HBB) that does not carry the sickle-cell mutation (FIG. 17B). FIG. 18 shows that the majority of the HBD sequence that got incorporated in the HBB locus was in the region between the nickase cuts. In contrast, a low frequency of gene conversion was observed when the N863 nicase was used (FIG. 17A). In the case of Cas9 N863A nickase, a majority of the gene editing events were insertions in which the inserted part was a duplication of the overhangs (FIGS. 19A-19B).

To test the effect that different lesions had on the engagement of HDR, a donor template was provided as a single strand oligo or as ds DNA donor. In both cases the length of the donor is approximately 170 bp with 60 bp of homology outside the nicks and with 8 mismatches (FIG. 20A). As shown in FIG. 20B, the Cas9 D10A nickase that resulted in a 5′ overhang gave a significantly higher rate of HDR, especially when using the upper stand as a single-strand oligo donor. FIG. 20C shows different forms of donors (dsDNA, upper stand, and lower strand) and there contribution to HDR.

In summary, Cas9 nickases (D10A and N863A) showed comparable levels of efficacy compared to wildtype Cas9. Different DNA ends engage different repair pathways. The use of a wildtype Cas9 generates a blunt end, which are preferentially repaired by canonical NHEJ. Use of a Cas9 nickase with two gRNAs generates either 3′ or 5′ overhangs, which are not suitable substrates to be repaired by canonical NHEJ but can be repaired by alternative pathways.

The 5′ protruding end was mostly repaired through a mechanism called gene conversion in which the HBB gene is repaired by using the HBD locus as a template. Use of nickase is advantageous to promote HDR. In the experiments in which a donor was provided, a significantly higher rate of HDR was observed using a nickase compared to the wildtype Cas9. The nature of the donor template also influences the outcome as HDR was preferentially observed when an SS Oligo was used.

Example 7: Assessment of Gene Targeting in Hematopoietic Stem Cells

Transplantation of autologous CD34+ hematopoietic stem cells (HSCs, also known as hematopoietic stem/progenitor cells or HSPCs) genetically modified to correct the Sickle Cell Disease (SCD) mutation in the human β-hemoglobin gene (HBB) would prevent deformability (sickling) after deoxygenation in the erythrocyte progeny of corrected HSCs which could ameliorate symptoms associated with SCD. Genome editing with the CRISPR/Cas9 platform precisely alters endogenous gene targets by creating an indel at the targeted cut site that can lead to knock down of gene expression at the edited locus. In this Example, genome editing in the human K562 bone marrow erythroleukemia cell line, which serve as a proxy for HSCs and which can be predictive of genome editing in HSCs, were electroporated with Cas9 mRNA and gRNA HBB-8 and gRNA HBB-15 to induce gene editing at the human HBB locus.

K562 cells were grown in RPMI media (Life Technologies) containing 10% fetal bovine serum (FBS). For the RNA electroporation, the Maxcyte GT device (maxcyte.com/) was used. S. pyogenes Cas9 mRNA and gRNA HBB-15 and gRNA HBB-8 were prepared by in vitro transcription using linearized plasmid DNA as templates and the Ambion mMessage mMachine® T7 Ultra Transcription kit (Life Technologies) according to the manufacturer's instructions. In this embodiment, both the Cas9 and gRNA were in vitro transcribed using a T7 polymerase. For example, a 5′ ARCA cap was added to both RNA species simultaneous to transcription while a polyA tail was added after transcription to the 3′ end of the RNA species by an E. coli polyA polymerase. Capped and tailed gRNA HBB-8 and gRNA HBB-15 were complexed at room temperature with S. pyogenes H-NLS-Cas9 protein at a molar ratio of ˜25:1 (gRNA:Cas9 protein) in a total of 30 pg RNP. Briefly, three million K562 cells were suspended in 100 μL Maxcyte EP buffer and transferred to the RNP solution (13 μL). In addition, K562 cells were electroporated with S. pyogenes Cas9 mRNA and each of the gRNA HBB-8 and gRNA HBB-15. For the mRNA/gRNA electroporation with the Maxcyte device, 10 μg of gRNA HBB-8 (or 10 μg of HBB gRNA HBB-15) were mixed with 10 μg of Cas9 mRNA. Four million K562 cells were suspended in 100 μL Maxcyte EP buffer and then transferred to the mRNA/gRNA solution (13 μL). K562 cells mixed with either RNP or RNA were electroporated with the Maxcyte GT device. At 48 hours after electroporation, K562 cells were enumerated by trypan blue exclusion and were determined to have >88% viability in the electroporated cell populations. Genomic DNA was extracted from K562 cells 48 hours after electroporation and HBB locus-specific PCR reactions were performed.

In order to detect indels at the HBB locus, T7E1 assays were performed on HBB locus-specific PCR products that were amplified from genomic DNA samples from electroporated K562 cells and the percentage of indels detected at the HBB locus was calculated (FIG. 21 ).

Co-delivery of 10 μg RNP which contains wild-type S. pyogenes Cas9 protein with HBB gRNA 8 or HBB gRNA 15 resulted in 26.8% and 16.1% indels, respectively, at the HBB locus in gDNA from K562 cells (molar ratio protein: gRNA 24:1). Co-delivery of Cas9 mRNA with gRNA HBB-8 or HBB-15 led to 66.9% and 29.5% indels at the HBB locus in gDNA from K562 cells (10 μg of each RNA/4 million cells). This example shows that delivery of Cas9 mRNA/gRNA and Cas9 RNPs leads to editing of the HBB locus in a relevant bone marrow derived hematopoietic cell line (K562 cells). Clinically, transplantation of autologous HSCs in which the HBB locus has been edited to correct the genetic mutation that causes red blood cell sickling could be used to ameliorate symptoms of SCD.

INCORPORATION BY REFERENCE

All publications, patents, and patent applications mentioned herein are hereby incorporated by reference in their entirety as if each individual publication, patent or patent application was specifically and individually indicated to be incorporated by reference. In case of conflict, the present application, including any definitions herein, will control.

EQUIVALENTS

Those skilled in the art will recognize, or be able to ascertain using no more than routine experimentation, many equivalents to the specific embodiments of the invention described herein. Such equivalents are intended to be encompassed by the following claims. 

1-189. (canceled)
 190. A gRNA molecule comprising a targeting domain which is complementary with a target domain from the HBB or BCL11A gene.
 191. The gRNA molecule of claim 190, wherein said targeting domain is configured to provide a cleavage event selected from a double strand break and a single strand break, within 500, 400, 300, 200, 100, 50, 25, or 10 nucleotides of an SCD target point position or an SCD target knockout position.
 192. The gRNA molecule of claim 190, wherein said targeting domain is configured to target an early coding region or an enhancer region of the BCL11A gene.
 193. The gRNA molecule of claim 190, wherein said targeting domain is configured to target a mutation in the HBB gene.
 194. The gRNA molecule of claim 190, wherein said targeting domain is configured to target the promoter region of the BCL11A gene.
 195. The gRNA molecule of claim 190, wherein said targeting domain comprises or consists of a sequence that is the same as, or differs by no more than 3 nucleotides from, a targeting domain sequence from any of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or
 31. 196. A nucleic acid that comprises a nucleotide sequence that encodes a gRNA molecule comprising a targeting domain that is complementary with an SCD target domain in the HBB gene or BCL11A gene.
 197. The nucleic acid of claim 196 wherein said targeting domain is configured to provide a cleavage event selected from a double strand break and a single strand break, within 500, 400, 300, 200, 100, 50, 25, or 10 nucleotides of the SCD target point position or the SCD target knockout position.
 198. The nucleic acid of claim 196, wherein said targeting domain is configured to target an early coding region or an enhancer region of the BCL11A gene.
 199. The nucleic acid of claim 196, wherein said targeting domain is configured to target a mutation in the HBB gene.
 200. The nucleic acid of claim 196, wherein said targeting domain is configured to target the promoter region of the BCL11A gene.
 201. The nucleic acid of claim 196, wherein said targeting domain comprises or consists of a sequence that is the same as, or differs by no more than 3 nucleotides from, a targeting domain sequence from any of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or
 31. 202. The nucleic acid of claim 196, further comprising a sequence that encodes a Cas9 molecule.
 203. A method of altering a cell comprising contacting said cell with: (a) a gRNA molecule comprising a targeting domain which is complementary with a target domain from the HBB or BCL11A gene; and (b) a Cas9 molecule.
 204. The method of claim 203, wherein said targeting domain is configured to target an early coding region or an enhancer region of the BCL11A gene.
 205. The method of claim 203, wherein said targeting domain is configured to target a mutation in the HBB gene.
 206. The method of claim 203, wherein said targeting domain is configured to target the promoter region of the BCL11A gene.
 207. The method of claim 203, wherein said targeting domain comprises or consists of a sequence that is the same as, or differs by no more than 3 nucleotides from, a targeting domain sequence from any of Tables 1A-1D, 2A-2F, 3A-3C, 4A-4E, 5A-5E, 6A-6B, 7A-7D, 8A-8D, 9, 10A-10D, 11A-11D, 12, 13A-13D, 14A-14C, 15A-15D, 16A-16E, 17A-17B, 18A-18C, 19A-19E, 20A-20C, 21A-21E, 22A-22E, 23A-23C, 24A-24D, 25A-25B, 26, or
 31. 208. The method of claim 203, wherein said cell is selected from the group consisting of an erythroid cell, a bone marrow cell, and a stem cell.
 209. The method of claim 203, wherein said contacting step is performed ex vivo. 